Imaging apparatus and shutter driving method

ABSTRACT

To enable correction or adjustment of a curtain travel curve in a case of driving an opening and closing blade by a power source in which a motor mechanism and a spring mechanism are combined. Provided are the motor mechanism that generates a traveling torque of the opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil, and the spring mechanism that generates the traveling torque of the opening and closing blade together with the motor mechanism. In this case, a control unit capable of individually controlling a time length from the start of the electric conduction to the coil to the start of traveling of the opening and closing blade, and a value of a current to be supplied to the coil is provided.

TECHNICAL FIELD

The present technology relates to an imaging apparatus and more particularly to a mechanical shutter driving technology.

BACKGROUND ART

A mechanical shutter in an imaging apparatus (camera) is usually configured to drive an opening and closing blade using an electromagnetic motor, but a mechanical shutter provided with a spring mechanism in addition to an electromagnetic motor and which assists a drive force by the motor with a spring is known.

Patent Documents 1 and 2 below disclose techniques of obtaining a sufficient traveling speed with assistance of a spring in a case where a blade traveling speed is insufficient depending on an electromagnetic motor.

Patent Document 3 discloses a technique regarding torque adjustment of an electromagnetic motor.

CITATION LIST Patent Document

-   Patent Document 1: Japanese Utility Model Publication No. 61-44191 -   Patent Document 2: Japanese Patent No. 1391463 -   Patent Document 3: Japanese Patent Application Laid-Open No.     58-149027

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

In the case of a hybrid power shutter in which an electromagnetic motor and an assist spring are combined, there are two power sources, and a curtain travel curve may change depending on characteristics of the two power sources. Then, a change in the curtain travel curve only at an initial stage or at or after a middle stage may occur. The change occurs in a case where one of force amounts of the electromagnetic motor and the assist spring changes due to aging, an environment, manufacturing variations, or the like, for example.

For this reason, correction of the torque variation for each of the electromagnetic motor and the assist spring is required.

Note that, as described in Patent Document 3, a torque adjustment method for an electromagnetic motor is known. However, in a case of a blade opening and closing device having an assist spring, a variation or change in a force amount component of the spring cannot be sufficiently corrected.

Therefore, an object of the present technology is to enable appropriate control of curtain travel in a hybrid power shutter in which an electromagnetic motor and an assist spring are combined.

Solutions to Problems

An imaging apparatus according to the present technology includes a motor mechanism configured to generate a traveling torque of an opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil; a spring mechanism configured to generate the traveling torque of the opening and closing blade together with the motor mechanism; and a control unit configured to be able to individually control a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade, and a current value to be supplied to the coil.

The motor mechanism and the spring mechanism are provided to drive the opening and closing blade that open and close as the mechanical shutter. For example, when restriction by a lock mechanism is released, the opening and closing blade is driven to travel by a combined torque of a motor torque and a spring torque. In this case, the time length from the start of the electric conduction to a point of time of the start of traveling (a point of time of the release of the restriction by the lock mechanism) and the value of the current to be supplied to the coil are made individually and variably controllable.

In the imaging apparatus according to the above-described present technology, it is conceivable that the control unit adjusts one or both of the time length and the current value to correct a traveling operation of the opening and closing blade.

In other words, the traveling torque at the initial stage or the traveling torque at or after the middle stage of the opening and closing blade is adjusted to correct the traveling operation to an original traveling state.

In the imaging apparatus according to the above-described present technology, it is conceivable that a counter configured to count the number of times of traveling of the opening and closing blade is further included, and the control unit performs the correction on the basis of a count value of the counter.

By counting the number of times of traveling of the opening and closing blade, correction execution determination based on a deterioration state over time is made.

In the imaging apparatus according to the above-described present technology, it is conceivable that a speed sensor of the opening and closing blade is further included, and the control unit performs the correction on the basis of detection information of the speed sensor.

A traveling speed of the opening and closing blade is made detectable by the speed sensor, and whether or not the traveling state of blades requires correction is determined according to the speed.

In the imaging apparatus according to the above-described present technology, it is conceivable that a temperature sensor configured to detect a temperature of the motor mechanism or the spring mechanism is further included, and the control unit performs the correction on the basis of detection information of the temperature sensor.

In other words, the state of the motor mechanism or the spring mechanism is estimated according to the temperature detected by the temperature sensor, and whether or not correction is necessary is determined.

In the imaging apparatus according to the above-described present technology, it is conceivable that the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism are further included and the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism are further included, and the control unit performs the correction of one or both of the front curtain mechanism and the rear curtain mechanism.

In other words, correction can be made in the mechanism that performs a shutter operation with a front curtain and a rear curtain.

In the imaging apparatus according to the above-described present technology, it is conceivable that the control unit adjusts one or both of the time length and the current value according to a selected imaging mode.

In other words, a traveling torque at an initial stage or a traveling torque at or after a middle stage of the opening and closing blade is adjusted to obtain the traveling state according to the imaging mode.

In the imaging apparatus according to the above-described present technology, it is conceivable that the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes longer than an exposure time of an end portion of the image in an up-down direction according to selection of an imaging mode for making a center of an image brighter than an end portion of the image in the up-down direction.

In other words, a curtain travel curve of the opening and closing blade is varied to take the exposure time long in the center of the image.

In the imaging apparatus according to the above-described present technology, it is conceivable that the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes shorter than an exposure time of upper and lower end portions of the image in an up and down direction according to selection of an imaging mode for making upper and lower end portions of an image brighter than a center of the image in the up and down direction.

In other words, a curtain travel curve of the opening and closing blade is varied to take the exposure time short in the center of the image.

In the imaging apparatus according to the above-described present technology, it is conceivable that the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism are further included and the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism are further included, and the control unit performs the adjustment of one or both of the front curtain mechanism and the rear curtain mechanism.

In other words, in the mechanism that performs shutter operation with a front curtain and a rear curtain, the curtain travel curves of the front curtain and the rear curtain are varied to obtain a special image effect.

In the imaging apparatus according to the above-described present technology, it is conceivable that a lock mechanism configured to restrict the traveling of the opening and closing blade not to start even by energization of the spring mechanism and the start of the electric conduction to the coil is further included.

When the restriction by the lock mechanism is released, the opening and closing blade is driven to travel by a combined torque of a motor torque and a spring torque.

In the imaging apparatus according to the above-described present technology, it is conceivable that the control unit varies the time length according to restriction release timing by the lock mechanism after the start of the electric conduction to the coil.

After the start of the electric conduction to the coil, a point of time of the release of the restriction by the lock mechanism is travel start timing of the opening and closing blade.

In the imaging apparatus according to the above-described present technology, it is conceivable that the motor mechanism includes a coil to which a drive current is supplied, and a magnet rotated with the electric conduction to the coil, the spring mechanism is configured to energize the magnet in a rotation direction, a drive body configured to cause the opening and closing blade to travel according to rotation of the magnet and including a portion to be locked, and the lock mechanism is configured to maintain the opening and closing blade not to start traveling by locking the portion to be locked.

The motor mechanism (so-called electromagnetic actuator) for driving the opening and closing blade includes the magnet rotated with the electric conduction to the coil, and a drive pair causes the opening and closing blade to travel with the rotation of the magnet.

In the imaging apparatus according to the above-described present technology, it is conceivable that the spring mechanism is configured to energize the magnet in the rotation direction.

The spring mechanism energizes the magnet constituting an electromagnetic actuator to provide the drive body with a spring torque for causing the opening and closing blade to travel.

A shutter driving method according to the present technology includes, as a shutter driving method of an imaging apparatus including the motor mechanism and the spring mechanism, a procedure of setting a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade; and a procedure of setting a current value to be supplied to the coil.

Thereby, the traveling torque at an initial stage and the traveling torque at or after a middle stage are controlled.

Effects of the Invention

According to the present technology, in a hybrid power shutter in which an electromagnetic motor and an assist spring are combined, a traveling torque at an initial stage that mainly varies in a state of the assist spring and a traveling torque at or after a middle stage mainly by the electromagnetic motor can be adjusted, and curtain travel can be appropriately controlled.

Note that effects described here are not necessarily limited, and any of effects described in the present disclosure may be exhibited.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates an embodiment of a blade opening and closing device and an imaging apparatus according to the present technology together with FIGS. 2 to 46, and is a perspective view illustrating the imaging apparatus.

FIG. 2 is a perspective view illustrating the imaging apparatus in a state of being viewed from a different direction from FIG. 1.

FIG. 3 is a schematic side view of the imaging apparatus.

FIG. 4 is a perspective view of the blade opening and closing device.

FIG. 5 is an exploded perspective view illustrating a part of the blade opening and closing device.

FIG. 6 is a front view illustrating an arrangement state of a first magnetic drive unit, a second magnetic drive unit, a first lock mechanism, and a second lock mechanism.

FIG. 7 is an exploded perspective view illustrating a configuration of the blade opening and closing device excluding a part of the blade opening and closing device.

FIG. 8 is an exploded perspective view illustrating a configuration of the blade opening and closing device excluding a part of the blade opening and closing device, in a state of being viewed from a different direction from FIG. 7.

FIG. 9 is an enlarged exploded perspective view illustrating a part of a housing case and one of the magnetic drive units.

FIG. 10 is an enlarged exploded perspective view illustrating a part of the housing case and one of the magnetic drive units, in a state of being viewed from a different direction from FIG. 9.

FIG. 11 is a front view of the housing case.

FIG. 12 is an exploded perspective view illustrating the magnetic drive units and the lock mechanisms.

FIG. 13 is an exploded perspective view illustrating the magnetic drive units and the lock mechanisms in a state of being viewed from a different direction from FIG. 12.

FIG. 14 is an enlarged perspective view illustrating a magnet and the like.

FIG. 15 is an enlarged perspective view illustrating the magnet and the like in a state of being viewed from a different direction from FIG. 14.

FIG. 16 is an enlarged cross-sectional view illustrating a configuration of a part of the magnetic drive units and the like.

FIG. 17 is an enlarged exploded perspective view illustrating a part of the housing case and a part of one of the magnetic drive units.

FIG. 18 is an enlarged front view illustrating a yoke and a coil.

FIG. 19 is an enlarged cross-sectional view taken along line XIX-XIX in FIG. 18.

FIG. 20 is an enlarged cross-sectional view taken along line XX-XX in FIG. 18.

FIG. 21 is an enlarged perspective view illustrating a power assist spring, a force amount adjusting part, an effective range adjusting part, and the like.

FIG. 22 is a back view illustrating an arrangement state of the first magnetic drive unit, the second magnetic drive unit, and the like.

FIG. 23 is an enlarged exploded perspective view illustrating a cover and each part supported by the cover.

FIG. 24 is an enlarged perspective view illustrating a cover and each part supported by the cover.

FIG. 25 is an enlarged perspective view illustrating the lock mechanism.

FIG. 26 is an enlarged perspective view illustrating the lock mechanism in a state of being viewed from a different direction from FIG. 25.

FIG. 27 is an enlarged front view illustrating the first lock mechanism and the second lock mechanism.

FIG. 28 is a schematic front view illustrating a state in which a first opening and closing blade is at a closed position and a second opening and closing blade is at an open position.

FIG. 29 illustrates an operation of the blade opening and closing device together with FIGS. 30 to 36, and is a front view illustrating a state in which a lock protrusion is engaged with a first engagement portion of an engagement piece.

FIG. 30 is a front view illustrating a state in which an energizing force in the same direction as a rotation direction of the magnet is provided from the power assist spring to the magnet.

FIG. 31 is a front view illustrating a state in which a lock lever is turned and the engagement of the lock protrusion with the engagement piece is released, following FIG. 29.

FIG. 32 is a front view illustrating a state in which provision of the energizing force from the power assist spring to the magnet is stopped, following FIG. 30.

FIG. 33 is a front view illustrating a state in which the magnet is rotated and the lock protrusion is slid on a sliding portion of the engagement piece, following FIG. 31.

FIG. 34 is a front view illustrating a state in which the magnet is rotated and a roller supported by an action lever is pressed by a pressing protrusion of a lever mounting member, following FIG. 33.

FIG. 35 is a front view illustrating a state in which an energizing force in an opposite direction to the rotation direction of the magnet is provided from the power assist spring to the magnet, following FIG. 32.

FIG. 36 is a front view illustrating a state in which the lock protrusion is engaged with a second engagement portion of the engagement piece, following FIG. 34.

FIG. 37 is a front view illustrating another arrangement state of the first magnetic drive unit, the second magnetic drive unit, the first lock mechanism, and the second lock mechanism.

FIG. 38 is a front view illustrating a state in which the first opening and closing blade and the second opening and closing blade are at the open position.

FIG. 39 is a schematic front view illustrating a state in which the first opening and closing blade is at the open position and the second opening and closing blade is at the closed position.

FIG. 40 is a front view illustrating a state where slid traveling is being performed.

FIG. 41 is a front view illustrating a state in which the first opening and closing blade and the second opening and closing blade are at the closed position.

FIG. 42 illustrates adjustment of the power assist spring by the force amount adjusting part together with FIG. 43, and is a back view illustrating a state before the adjustment is performed.

FIG. 43 is a back view illustrating a state in which the adjustment has been performed.

FIG. 44 illustrates adjustment of the power assist spring by the effective range adjusting part together with FIG. 45, and is a back view illustrating a state before the adjustment is performed.

FIG. 45 is a back view illustrating a state in which the adjustment has been performed.

FIG. 46 is a block diagram of a control configuration of the imaging apparatus according to the embodiment.

FIG. 47 is an explanatory diagram of a control signal of the embodiment.

FIG. 48 is explanatory diagrams of drive body torque curves of the embodiment.

FIG. 49 is explanatory diagrams in a case of increasing a torque at an initial stage of traveling of the embodiment.

FIG. 50 is explanatory diagrams in a case of increasing a torque at or after a middle stage of traveling of the embodiment.

FIG. 51 is a flowchart of a curtain travel curve correction processing of the embodiment.

FIG. 52 is flowcharts of correction necessity determination of the embodiment.

FIG. 53 is explanatory diagrams of special exposure of the embodiment.

FIG. 54 is a flowchart of processing of performing special exposure of the embodiment.

MODE FOR CARRYING OUT THE INVENTION

Hereinafter, an embodiment will be described in the following order.

<1. Shutter Mechanism of Imaging Apparatus>

<2. Control Configuration of Imaging Apparatus>

<3. Correction of Curtain Travel Curve>

<4. Special Exposure by Adjusting Curtain Travel Curve>

<5. Conclusion and Modification>

<1. Shutter Mechanism of Imaging Apparatus>

In an embodiment described below, an imaging apparatus of the present technology is applied to a still camera, and a blade opening and closing device of the present technology is applied to a focal plane shutter provided in the still camera.

Note that the scope of application of the present technology is not limited to a still camera and a focal plane shutter provided in the still camera. For example, the present technology can be widely applied to various imaging apparatuses incorporated in video cameras or other devices and various blade opening and closing devices such as irises provided in these imaging apparatuses.

In the following description, front-rear, right-left, and up-down directions are indicated according to a direction viewed from a photographer at the time of capturing an image with the still camera. Therefore, an object side is the front and the photographer side is the rear.

Note that the front-rear, up-down, and right-left directions described below are for convenience of description, and implementation of the present technology is not limited to these directions.

Furthermore, a lens group described below may include a single lens or a plurality of lenses and other optical elements such as an iris, in addition to a group configured by a single lens or a plurality of lenses.

[Schematic Configuration of Imaging Apparatus]

First, a schematic configuration of an imaging apparatus will be described (see FIGS. 1 to 3).

An imaging apparatus 1 is configured such that, for example, required parts are arranged inside and outside a flat and oblong housing 2, as illustrated in FIGS. 1 and 2. As illustrated in FIG. 1, the imaging apparatus 1 may be an apparatus to and from which an interchangeable lens 200 can be attached and detached.

A flash 3 is provided on a front surface of the housing 2. A shutter button 4, a zoom switch 5, and a power button 6 are provided on an upper surface of the housing 2 (see FIGS. 1 and 2). A display 7, various operation units 8, 8, and the like, a finder 9 are provided on a read surface of the housing 2.

Inside the housing 2, as illustrated in FIG. 3, an optical system 10 including a lens group, an optical element, and the like, a blade opening and closing device (focal plane shutter) 11 for controlling the amount of light taken in by the optical system 10, and an imaging element 12 for photoelectrically converting the light taken in via the blade opening and closing device 11 are arranged in order from the front side.

[Configuration of Blade Opening and Closing Device]

Hereinafter, a configuration of the blade opening and closing device 11 will be described (see FIGS. 4 to 27).

The blade opening and closing device 11 includes, as illustrated in FIGS. 4 to 6, a base body 13, a pressing plate 14, a housing case 15, a first magnetic drive unit 16, a second magnetic drive unit 17, covers 18 and 18, a first opening and closing blade 19, a second opening and closing blade 20, a first link 21, and a second link 22, and is arranged on a front surface side of the imaging element 12.

The base body 13 is formed in, for example, an oblong rectangular shape and has a rectangular opening 13 a penetrating in the front-rear direction (see FIGS. 4 and 5). The opening 13 a is made slightly larger than an effective incident region of light in an imaging surface of the imaging element 12. The effective incident region of light on the imaging surface is a region where light taken in by the optical system 10 and necessary for generating an image enters.

Upper and lower portions of the opening 13 a in the base body 13 are respectively provided as holding portions 23 and 23 serving as holding regions where the first opening and closing blade 19 and the second opening and closing blade 20 are held at open positions. One portion of side portions of the opening 13 a in the base body 13 is provided as a mounting portion 24 to which the housing case 15 is mounted.

Shaft insertion holes 24 a and 24 a are formed spaced in the up-down direction in the mounting portion 24. Shaft moving holes 24 b and 24 b are formed spaced in the up-down direction in the mounting portion 24, and the shaft moving holes 24 b and 24 b are respectively formed in arc shapes with the shaft insertion holes 24 a and 24 a as fulcrums.

The pressing plate 14 is formed in approximately the same size and shape as the base body 13, and has a transmission hole 14 a. The pressing plate 14 is mounted to the base body 13 from the front side with the first opening and closing blade 19 and the second opening and closing blade 20 sandwiched therebetween. In the state where the pressing plate 14 is mounted to the base body 13, the transmission hole 14 a is located right in front of the opening 13 a.

Pin mounting holes 14 b and 14 b are formed spaced in the up-down direction in one end portion of a side portion of the pressing plate 14. Clearance holes 14 c and 14 c are formed spaced in the up-down direction in the pressing plate 14, and the clearance holes 14 c and 14 c are respectively formed in arc shapes with the pin mounting holes 14 b and 14 b as fulcrums.

The housing case 15 contains a nonmagnetic material such as a resin material, and has front surfaces 25 and 25, side surfaces 26, 26, and the like, a connecting surface 27, and partitions 28 and 28 (see FIGS. 7 to 11).

The front surfaces 25 and 25 are located spaced in the up-down direction, and the side surfaces 26, 26, and the like have front edges respectively continuous with right and left side edges of the front surfaces 25 and 25. The connecting surface 27 faces in the front-rear direction and has up and down edges respectively continuous with rear end portions in lower edges of the upper side surfaces 26 and 26 and rear end portions in upper edges of the lower side surfaces 26 and 26. The partitions 28 and 28 are formed in plate shapes facing the up-down direction, and have rear edges respectively continuous with upper and lower edges of the connecting surface 27. The partitions 28 and 28 have right and left side edges respectively continuous with the lower edges of the upper side surfaces 26 and 26 and the upper edges of the lower side surfaces 26 and 26, and have front edges respectively continuous with a lower edge of the upper front surface 25 and an upper edge of the lower front surface 25.

The housing case 15 is divided into three parts in the up-down direction by the partitions 28 and 28, and is formed in a symmetrical shape in the up-down direction with respect to the center of the connecting surface 27 in the up-down direction (see FIG. 11). In the housing case 15, an upper space partitioned by the upper partition 28 is formed as a first arrangement portion 15 a, a lower space partitioned by the lower partition 28 is formed as a second arrangement portion 15 b, and a space between the partitions 28 and 28 is formed as a third arrangement portion 15 c. The first arrangement portion 15 a is opened rearward and upward, the second arrangement portion 15 b is opened backward and downward, and the third arrangement portion 15 c is opened backward and the right and left.

Note that, in the blade opening and closing device 11, the housing case 15 is formed in a symmetrical shape in the up-down direction, and the two magnetic drive units to be described below arranged in the first arrangement portion 15 a and the second arrangement portion 15 b are also symmetrically configured in the up-down direction. Therefore, hereinafter, the configuration on the first arrangement portion 15 a side will be mainly described, and the configuration on the second arrangement portion 15 b side will be described as needed.

A portion on the third arrangement portion 15 c side of the front surface 25 is displaced rearward and located (see FIG. 9). A part is displaced rearward and located in this manner, so that an arrangement recess 15 d open at least forward is formed in the front surface 25.

An insertion hole 25 a penetrating in the front-rear direction is formed in the portion of the front surface 25, where the arrangement recess 15 d is formed, and the insertion hole 25 a communicates with the first arrangement portion 15 a. In the front surface 25, as illustrated in FIGS. 9 to 11, first positioning holes 25 b and 25 b are formed spaced in the right-left direction in an upper end portion, and second positioning holes 25 c and 25 c are formed spaced in the right-left direction in an approximate center in the up-down direction.

An insertion protrusion 25 d protrudes rearward from an approximate center of the front surface 25. A part of the side surface 26 is provided as an engaging protrusion 26 a. The engaging protrusion 26 a is provided between two slits spaced in the up-down direction, and is elastically deformable such that a rear end portion is displaced in the right-left direction. A rear end portion of the engaging protrusion 26 a is provided as a locking claw 26 b.

A support plate 29 is mounted to the mounting portion 24 of the base body 13 from the rear side (see FIGS. 4 and 5). First shaft insertion holes 29 a and 29 a and second shaft insertion holes 29 b and 29 b are formed spaced in the up-down direction in the support plate 29 (see FIGS. 7 and 8). The second shaft insertion holes 29 b and 29 b are formed in arc shapes with the first shaft insertion holes 29 a and 29 a as fulcrums. Bearing holes 29 c and 29 c are formed in an approximate center in the up-down direction in the support plate 29. The bearing holes 29 c and 29 c are located in right and left end portions.

In the state where the support plate 29 is mounted to the mounting portion 24 of the base body 13, the first shaft insertion holes 29 a and 29 a are respectively located right behind the shaft insertion holes 24 a and 24 a of the base body 13, and the second shaft insertion holes 29 b and 29 b are respectively located right behind the shaft moving holes 24 b and 24 b of the base body 13.

The housing case 15 is mounted to the support plate 29 from the rear side (see FIG. 4). In the state where the housing case 15 is mounted to the support plate 29, the insertion holes 25 a and 25 a of the housing case 15 are respectively located on the rear side of the first shaft insertion holes 29 a and 29 a of the support plate 29.

The first magnetic drive unit 16 includes a magnet 30, a coil 31, and a yoke 32, and is arranged in the first arrangement portion 15 a of the housing case 15 (see FIGS. 6 and 9).

The magnet 30 is formed in an approximately cylindrical shape with an axial direction set to the front-rear direction, and is, for example, two-pole magnetized. First positioning notches 30 a and 30 a are formed spaced in a peripheral direction in an outer periphery in a front end portion of the magnet 30 (see FIGS. 12 and 13). Second positioning notches 30 b and 30 b are formed spaced in the peripheral direction in an outer periphery in a rear end portion of the magnet 30.

A lever mounting member 33 is attached to a front surface of the magnet 30 (see FIGS. 12 to 15). The lever mounting member 33 has a base 34 formed in an approximately annular shape and protrusions 35 and 35 protruding forward from an outer periphery of the base 34.

Positioning protrusions 34 a and 34 a protruding rearward are provided spaced in the peripheral direction in an outer periphery in a rear end portion of the base 34. A pressing protrusion 34 b protruding outward is provided on an outer peripheral surface of the base 34. A space inside the protrusions 35 and 35 in the lever mounting member 33 is formed as a mounting space 33 a.

The lever mounting member 33 is mounted to the magnet 30 in a state where the positioning protrusions 34 a and 34 a are respectively inserted and positioned in the first positioning notches 30 a and 30 a.

A spring bearing member 36 is mounted to a rear surface of the magnet 30. The spring bearing member 36 has a base 37 formed in an approximately annular shape, and a first spring bearing protrusion 38 and a second spring bearing protrusion 39 protruding rearward from an outer periphery of the base 37.

Positioning protrusions 37 a and 37 a protruding forward are provided spaced in the peripheral direction in an outer periphery in a front end portion of the base 37. The first spring bearing protrusion 38 and the second spring bearing protrusion 39 are formed in approximately arc shapes, and are provided spaced in the peripheral direction. One end edges on the same side in the peripheral direction of the first spring bearing protrusion 38 and the second spring bearing protrusion 39 are respectively formed as a first spring bearing edge 38 a and a second spring bearing edge 39 a.

The spring bearing member 36 is mounted to the magnet 30 in a state where the positioning protrusions 37 a and 37 a are respectively inserted and positioned in the second positioning notches 30 b and 30 b.

A drive lever 40 is mounted to the lever mounting member 33. The drive lever 40 is formed such that a connecting plate 41 formed in an annular shape, an arm plate 42 radially protruding from the connecting plate 41, and an engagement piece 43 protruding from the connecting plate 41 in a radial direction different from the arm plate 42 are integrally formed.

A connecting shaft 44 is mounted to a distal end portion of the arm plate 42, and the connecting shaft 44 protrudes forward from the arm plate 42. The engagement piece 43 is formed in an approximate fan shape, and both side edges in the peripheral direction are respectively formed as a first engagement portion 43 a and a second engagement portion 43 b, and an outer peripheral edge between the first engagement portion 43 a and the second engagement portion 43 b is formed as a sliding portion 43 c. The engagement piece 43 functions as a portion to be locked.

The drive lever 40 is mounted to the lever mounting member 33 in a state where a portion including the connecting plate 41 is inserted in the mounting space 33 a, and the arm plate 42 and the engagement piece 43 protrude outward from an outer periphery of the lever mounting member 33.

A bearing sleeve 45 is inserted into and fixed to a central portion of the connecting plate 41 of the drive lever 40, a central portion of the lever mounting member 33, a central portion of the magnet 30, and a central portion of the spring bearing member 36 (see FIGS. 12, 13, and 16). A rotation shaft 46 is inserted into the bearing sleeve 45, and the drive lever 40, the lever mounting member 33, the magnet 30, the spring bearing member 36, and the bearing sleeve 45 are integrally rotatable about the rotation shaft 46 as a fulcrum (see FIGS. 7, 8, and 16). A portion other than both end portions in the axial direction of the rotation shaft 46 is inserted in the bearing sleeve 45.

The yoke 32 of the first magnetic drive unit 16 includes, as illustrated in FIGS. 9, 10, 17, and 18, connecting parts 47 and 47 located spaced in the right-left direction, a coil mounting part 48 located between the connecting parts 47 and 47, and magnet arranging parts 49 and 49 protruding from the connecting parts 47 and 47 in a direction of approaching each other.

The connecting parts 47 and 47 are formed in a flat plate shape facing the right-left direction, first case-side positioning protrusions 50 and 50 protruding forward are respectively provided on one end portions 47 a and 47 a in the up-down direction, and cover-side positioning protrusions 51 and 51 protruding rearward are respectively provided on the other end portions 47 b and 47 b in the up-down direction.

The coil mounting part 48 is formed in a prismatic shape, for example, and is provided at a position close to the one end portions 47 a and 47 a of the connecting parts 47 and 47. Therefore, the one end portions 47 a and 47 a of the connecting parts 47 and 47 are at positions protruding from the coil mounting part 48 in the up-down direction. The coil mounting part 48 is provided at a position where the coil mounting part 48 connects inner portions of front and rear ends of the connecting parts 47 and 47 in the front-rear direction.

The magnet arranging parts 49 and 49 are located spaced in the up-down direction with respect to the coil mounting part 48. Front surfaces of the magnet arranging parts 49 and 49 are located on the same plane as front surfaces of the connecting parts 47 and 47. Facing surfaces of the magnet arranging parts 49 and 49 are formed as concave arcuate surfaces 49 a and 49 a.

A gap 32 a is formed between end edges of the magnet arranging parts 49 and 49 in a protruding direction from the connecting parts 47 and 47. The magnet arranging parts 49 and 49 are provided with protrusions 49 b and 49 b protruding from end portions on the connecting parts 47 and 47 sides toward the coil mounting part 48. The protrusions 49 b and 49 b are provided with second case-side positioning protrusions 52 and 52 protruding forward.

In the yoke 32, a cross-sectional area A (see FIG. 19) of the connecting part 47 and a cross-sectional area B (see FIG. 20) of the coil mounting part 48 are made approximately the same. The cross-sectional area A and the cross-sectional area B are cross-sectional areas in a direction orthogonal to a direction in which a magnetic flux of the yoke 32 passes.

The coil 31 is mounted to the coil mounting part 48 in an externally fitting manner (see FIGS. 17 to 20). The magnet 30 is inserted between the magnet arranging parts 49 and 49 so that the magnet 30 is rotatable in a direction around the axis (see FIG. 9).

At the electric conduction to the coil 31, a magnetic flux passing through the yoke 32 is generated. As described above, in the yoke 32, the cross-sectional areas A and A of the connecting parts 47 and 47 and the cross-sectional area B of the coil mounting part 48 are made approximately the same, and the magnetic flux passing through the connecting parts 47 and 47 and the coil mounting part 48 is not attenuated. Therefore, performance degradation of the first magnetic drive unit 16 and the second magnetic drive unit 17 can be prevented.

Furthermore, in the yoke 32, the sizes of the connecting parts 47 and 47 are made larger than the size of the coil mounting part 48 in the axial direction (front-rear direction) of the rotation shaft of the magnet 30, and the sizes of the connecting parts 47 and 47 in the orthogonal direction (right-left direction) orthogonal to the arranging direction (up-down direction) of the coil mounting part 48 and the magnet arranging parts 49 and 49 are made smaller than the size of the coil mounting part 49 in the arranging direction.

Therefore, the size of the yoke 32 in the orthogonal direction becomes smaller than that in the case where the sizes of the connecting parts 47 and 47 in the orthogonal direction are made the same as the size of the coil mounting part 48 in the arranging direction, and thus downsizing of the yoke 32 can be achieved in the orthogonal direction. In particular, as described above, after avoiding occurrence of the attenuation of the magnetic flux passing through the connecting parts 47 and 47 and the coil mounting part 48 to prevent the performance degradation of the first magnetic drive unit 16 and the second magnetic drive unit 17 by making the cross-sectional areas A and A of the connecting parts 47 and 47 and the cross-sectional area B of the coil mounting part 48 be approximately the same, the downsizing of the yoke 32 in the orthogonal direction can be achieved.

Note that, as described above, even in the case where the sizes of the connecting parts 47 and 47 are made larger than the size of the coil mounting part 48 in the front-rear direction, and the connecting parts 47 and 47 are provided with the one end portions 47 a and 47 a protruding from the coil mounting part 48 in the yoke 32, the external shape of the coil 31 has a fixed size. Therefore, the combined size of the yoke 32 and the coil 31 cannot become unnecessarily large. Therefore, downsizing of the yoke 32 in the right-left direction can be achieved without making the sizes of the yoke 32 in the up-down and front-rear directions large.

The yoke 32 to which the coil 31 is mounted is arranged in the first arrangement portion 15 a of the housing case 15 (see FIG. 17). When the yoke 32 is arranged in the housing case 15, the first case-side positioning protrusions 50 and 50 are respect inserted into the first positioning holes 25 b and 25 b of the front surface 25 and the second case-side positioning protrusions 52 and 52 are respectively inserted into the second positioning holes 25 c and 25 c of the front surface 25, so that the yoke 32 is positioned with respect to the housing case 15. Furthermore, at this time, the insertion protrusion 25 d of the housing case 15 is inserted into the space between the magnet arranging parts 49 and 49 of the coil 31 and the yoke 32, and the locking claws 26 b and 26 b of the engaging protrusions 26 a and 26 a, which are elastically restored after elastically deformed, are locked with rear edges of the connecting parts 47 and 47 of the yoke 32, so that the yoke 32 is held in the housing case 15.

The first case-side positioning protrusions 50 and 50 of the yoke 32 are respectively provided on the one end portions 47 a and 47 a of the connecting parts 47 and 47, and the one end portions 47 a and 47 a are not portions where the yokes 32 are made unnecessarily large, as described above. Furthermore, the second case-side positioning protrusions 52 and 52 of the yoke 32 are provided on the protrusions 49 b and 49 b protruding toward the coil mounting part 48 of the magnet arranging parts 49 and 49, and the protrusions 49 b and 49 b are portions existing inside the external shape of the yoke 32 and are not portions where the yokes 32 are made unnecessarily large.

Therefore, by providing the first case-side positioning protrusions 50 and 50 on the one end portions 47 a and 47 a and providing the second case-side positioning protrusions 52 and 52 on the protrusions 49 b and 49 b, high positioning accuracy of the yoke 32 to the housing case 15 can be secured without increasing the yoke 32 in size.

Furthermore, the one end portions 47 a and 47 a of the connecting parts 47 and 47 are portions protruding upward and downward with respect to the coil mounting part 48, and the protrusions 49 b and 49 b of the magnet arranging parts 49 and 49 are portions protruding toward the coil 31. Therefore, the one end portions 47 a and 47 a and the protrusions 49 b and 49 b are not portions where the magnetic flux passes, and are not portions where the magnetic flux generated in the yoke 32 is attenuated.

Therefore, even if the first case-side positioning protrusions 50 and 50 and the second case-side positioning protrusions 52 and 52 are provided on the one end portions 47 a and 47 a and the protrusions 49 b and 49 b, the magnetic flux generated in the yoke 32 is not affected, and the high positioning accuracy of the yoke 32 to the housing case 15 can be secured after securing favorable functionality of the first magnetic drive unit 16 and the second magnetic drive unit 17.

Furthermore, since the one end portions 47 a and 47 a and the protrusions 49 b and 49 b are not portions where the magnetic flux generated in the yoke 32 is attenuated, for example, it is possible that insertion holes are respectively formed in the one end portions 47 a and 47 a and the protrusions 49 b and 49 b, pins that are different members from the yoke 32 are inserted into the respective insertion holes, and these pins are provided as the first case-side positioning protrusions 50 and 50 and the second case-side positioning protrusions 52 and 52.

In the case where the yoke 32 is arranged in the housing case 15, the space between the magnet arranging parts 49 and 49 is located right behind the insertion hole 25 a of the front surface 25 (see FIG. 9).

The second magnetic drive unit 17 is arranged in the second arrangement portion 15 b of the housing case 15 (see FIG. 6). Since the second magnetic drive unit 17 has the same configuration as the first magnetic drive unit 16 and is arranged in a symmetric (line-symmetric) state in the up-down direction, description of the second magnetic drive unit 17 is omitted. Note that the drive lever 40 of the first magnetic drive unit 16 is provided as a first drive lever, and the drive lever 40 of the second magnetic drive unit 17 is provided as a second drive lever.

In the state where the drive lever 40 is mounted to the lever mounting member 33, and the lever mounting member 33 and the spring bearing member 36 are mounted to the magnet 30, the magnet 30 is inserted into the insertion hole 25 a of the front surface 25 and between the magnet arranging parts 49 and 49 of the yoke 32 and is arranged in the housing case 15 (see FIG. 16).

In the state where the magnet 30 is arranged in the housing case 15, the portion other than both end portions in the axial direction of the rotation shaft 46 is inserted in the bearing sleeve 45, and the rotation shaft 46 is fixed in a state where a front end portion is inserted in the first shaft insertion hole 29 a of the support plate 29.

The connecting shaft 44 mounted to the arm plate 42 of the drive lever 40 is inserted into the shaft moving hole 24 b of the base body 13, a portion close to one end of the first link 21 or the second link 22, and the clearance hole 14 c of the pressing plate 14 (see FIG. 5).

A spring support member 53 is mounted to a rear end portion of the rotation shaft 46 (see FIG. 16). The spring support member 53 has an approximately cylindrical support portion 53 a having an axial direction set to the front-rear direction and a flange 53 b projecting outward from a front end portion of the support portion 53 a, and at least a part of the support portion 53 a is mounted to the rotation shaft 46 by press fitting or the like. In the state where the spring support member 53 is mounted to the rotation shaft 46, the flange 53 b is located facing a rear surface of the base 37 of the spring bearing member 36.

A power assist spring 55 is supported on the spring support member 53 (see FIGS. 12, 13, and 16). The power assist spring 55 is, for example, a torsion coil spring, and includes a coil part 55 a, a first arm 55 b, and a second arm 55 c. The power assist spring 55 has the coil part 55 a located between the spring bearing protrusions 38 and 39 of the spring bearing member 36 in a state where the coil part 55 a is supported by the support portion 53 a of the spring support member 53 (see FIGS. 17 and 21). The power assist spring 55 has the first arm 55 b and the second arm 55 c be respectively engageable with the first spring bearing edge 38 a and the second spring bearing edge 39 a of the spring bearing member 36.

In the state where the power assist spring 55 is supported by the spring support member 53, a pressing ring 54 is mounted to a portion on a rear end side of the spring support member 53, and dropping off of the power assist spring 55 from the spring support member 53 is prevented by the pressing ring 54.

In the state where the first magnetic drive unit 16 and the second magnetic drive unit 17 are housed in the housing case 15 as described above, the covers 18 and 18 are mounted to the housing case 15 (see FIGS. 4, 7, 8, and 16). The housing case 15, the first magnetic drive unit 16, and the second magnetic drive unit 17 are covered with the cover 18 from behind (see FIGS. 21 and 22).

As described above, in the blade opening and closing device 11, the housing case 15 mounted to the base body 13 is provided, and the first magnetic drive unit 16 and the second magnetic drive unit 17 are housed in the housing case 15.

Therefore, members separately housing the first magnetic drive unit 16 and the second magnetic drive unit 17 are not required and the number of parts can be reduced. In addition, since both the first magnetic drive unit 16 and the second magnetic drive unit 17 are housed in the housing case 15, the first magnetic drive unit 16 and the second magnetic drive unit 17 can be brought close to each other, and the blade opening and closing device 11 can be downsized.

The cover 18 includes a first pressing surface part 56 facing the front-rear direction and a second pressing surface part 57 protruding forward from one end portion in the up-down direction of the first pressing surface part 56 (see FIGS. 23 and 24). A coil arrangement hole 18 a is formed at a position extending from the first pressing surface part 56 to the second pressing surface part 57 in the cover 18.

A member holding hole 56 a is formed in the first pressing surface part 56. In the first pressing surface part 56, fulcrum holes 56 b and 56 b are formed spaced in the right-left direction at positions on an opposite side of the coil arrangement hole 18 a across the member holding hole 56 a. In the first pressing surface part 56, lever stop holes 56 c and 56 c are formed spaced in the right-left direction between the member holding hole 56 a and the coil arrangement hole 18 a, and the lever stop holes 56 c and 56 c are formed in arc shapes with the fulcrum holes 56 b and 56 b as fulcrums. In the first pressing surface part 56, a working hole 56 d is formed between the lever stop holes 56 c and 56 c. In the first pressing surface part 56, positioning holes 56 e and 56 e are formed outside the fulcrum holes 56 b and 56 b in the right-left direction.

The cover 18 is mounted to the housing case 15 by screws or the like. When the cover 18 is mounted to the housing case 15, the cover-side positioning protrusions 51 and 51 of the yoke 32 are respectively inserted into the positioning holes 56 e and 56 e of the cover 18, so that the positioning between the yoke 32 and the cover 18 is performed.

In the state where the cover 18 is mounted to the housing case 15, the first arrangement portion 15 a is closed by the cover 18, and the coil 31 is arranged in a state where a part of the coil 31 is inserted in the coil arrangement hole 18 a (see FIG. 4). A rear end portion of the spring support member 53 mounted to the rear end portion of the rotation shaft 46 is inserted into the member holding hole 56 a of the cover 18, and the spring support member 53 is mounted to the first pressing surface part 56 (see FIG. 16).

A force amount adjusting part 58 and an effective range adjusting part 59 are turnably supported on the front side of the first pressing surface part 56 in the cover 18 (see FIGS. 23 and 24).

The force amount adjusting part 58 is formed in a plate shape facing the front-rear direction, and is turnably supported by the first pressing surface part 56. The force amount adjusting part 58 is located on an inner surface side of the first pressing surface part 56 and includes a portion to be supported 60 supported by the first pressing surface part 56 and a spring pressing portion 61 protruding forward from one end portion of the portion to be supported 60. In the portion to be supported 60, a position adjustment screw hole 60 a is formed at a position near one end, and a shaft insertion hole 60 b is formed at a position near the other end. The effective range adjusting part 59 is formed in a shape symmetrical to the force amount adjusting part 58 in the right-left direction, and is turnably supported by the first pressing surface part 56. The effective range adjusting part 59 is located on the inner surface side of the first pressing surface part 56, and includes a portion to be supported 62 and a spring pressing portion 63. A position adjustment screw hole 62 a and a shaft insertion hole 62 b are formed in the portion to be supported 62.

The force amount adjusting part 58 is turnably supported by the first pressing surface part 56 by a spindle 64 inserted into the shaft insertion hole 60 b and mounted to one of the fulcrum holes 56 b of the first pressing surface part 56. The effective range adjusting part 59 is turnably supported by the first pressing surface part 56 by a spindle 64 inserted into the shaft insertion hole 62 b and mounted to the other fulcrum hole 56 b of the first pressing surface part 56.

The force amount adjusting part 58 and the effective range adjusting part 59 are turned with respect to the cover 18 about the spindles 64 and 64 as fulcrums, respectively.

In the blade opening and closing device 11, set screws 65 and 65 are respectively inserted into the lever stop holes 56 c and 56 c of the first pressing surface part 56 from the rear and screwed with the position adjustment screw hole 60 a and the position adjustment screw hole 62 a, so that the force amount adjusting part 58 and the effective range adjusting part 59 can be held at desired turning positions with respect to the first pressing surface part 56.

At least a part of a first lock mechanism 66 and at least a part of a second lock mechanism 67 are arranged in the third arrangement portion 15 c of the housing case 15 (see FIG. 6). Note that, although the first lock mechanism 66 and the second lock mechanism 67 are positioned in a point-symmetric state, the first lock mechanism 66 and the second lock mechanism 67 have the same configuration. Therefore, hereinafter, the configuration of the first lock mechanism 66 will be described and description of the configuration of the second lock mechanism 67 is omitted.

The first lock mechanism 66 includes an attracting body 68, an action lever 69, and a lock lever 70 (see FIGS. 12, 13, 25, and 26).

The attracting body 68 has a lock yoke 71, a lock magnet 72, and lock coils 73 and 73. The attracting body 68 is fixed to the housing case 15.

The lock yoke 71 has a holding portion 71 a for holding the lock magnet 72 and attracting portions 71 b and 71 b protruding in the same direction in the right-left direction from the holding portion 71 a. As the lock magnet 72, a permanent magnet is used, for example. The lock coils 73 and 73 are respectively mounted to portions of the lock yoke 71 other than distal end portions of the attracting portions 71 b and 71 b.

The action lever 69 has a base plate 74, an action protrusion 75, a pressing protrusion 76, and a protrusion to be supported 77. The base plate 74 is formed in a shape facing the right-left direction. The action protrusion 75 protrudes approximately upward from one end portion in the front-rear direction of the base plate 74, and is formed in a shape facing the front-rear direction. The pressing protrusion 76 protrudes from a position in the action protrusion 75, the position being close to the base plate 74. The protrusion to be supported 77 protrudes approximately upward from the other end portion in the front-rear direction of the base plate 74, and is formed in a shape facing the front-rear direction.

A portion to be attracted 79 is supported by the base plate 74 via a compression coil spring 78. The portion to be attracted 79 is formed in an approximately rectangular plate shape in which a width in the front-rear direction is larger than a width in the up-down direction, and is supported by the base plate 74 with a support shaft 80 inserted in the base plate 74 and the compression coil spring 78. The compression coil spring 78 is compressed between the base plate 74 and the portion to be attracted 79, and the portion to be attracted 79 is energized by the compression coil spring 78 in a direction approaching the attracting body 68 in the right-left direction with respect to the base plate 74.

Bearings 81 and 81 are respectively mounted to a portion in the action protrusion 75, the portion being close to the base plate 74, and a distal end of the protrusion to be supported 77 in the action lever 69. A roller 82 is rotatably supported with a rotation fulcrum shaft 83 as a fulcrum at a position close to the distal end of the action protrusion 75. The rotation fulcrum shaft 83 has an axial direction set to the front-rear direction.

The action lever 69 is turnable with respect to the housing case 15 with a turning shaft 84 as a fulcrum. The turning shaft 84 is inserted into the action protrusion 75 of the action lever 69, the protrusion to be supported 77 of the action lever 69, and the bearings 81 and 81 mounted to the action lever 69, and both end portions in the axial direction are supported by the connecting surface 27 of the housing case 15 and the bearing hole 29 c of the support plate 29, and are rotatably supported by the housing case 15 and the support plate 29. The turning shaft 84 is inserted in an intermediate portion in a longitudinal direction (up-down direction) of the action protrusion 75. In the action protrusion 75, a portion on the side supporting a roller 81 with respect to the position where the turning shaft 84 is inserted is provided as a first portion 75 a, and a portion on the side of the base plate 74 is provided as a second portion 75 b. The first portion 75 a is longer than the second portion 75 b in the up-down direction.

The lock lever 70 is fixed at a position near a front end of the turning shaft 84. Therefore, the lock lever 70 is integrally turned with the turning shaft 84. The lock lever 70 functions as a lock part that locks the first opening and closing blade 19 and the second opening and closing blade 20 at the open position or the closed position. In the lock lever 70, the other end portion of an extending portion 70 a is supported by the turning shaft 84. The lock lever 70 has the extending portion 70 a extending in the approximately right-left direction, a lock protrusion 70 b protruding rearward from one end portion of the extending portion 70 a, and a spring bearing 70 c provided at a position close to the other end of the extending portion 70 a.

The pressing protrusion 76 of the action lever 69 is made engageable with the extending portion 70 a of the lock lever 70.

A lock spring 85 is supported by the turning shaft 84. The lock spring 85 is, for example, a torsion coil spring, and includes a coil part 85 a, a first arm 85 b, and a second arm 85 c. In the lock spring 85, the first arm 85 b is engaged with the spring bearing 70 c of the lock lever 70 and the second arm 85 c is engaged with the second portion 75 b of the action protrusion 75 in the action lever 69 in the state where the coil part 85 a is supported by the turning shaft 84 between the action lever 69 and the lock lever 70. Therefore, the action lever 69 and the lock lever 70 are energized in the opposite direction with the turning shaft 84 as a fulcrum by the energizing force of the lock spring 85, and the pressing protrusion 76 of the action lever 69 is engaged with the extending portion 70 a of the lock lever 70 in a state where a force against the energizing force is not provided in the lock spring 85.

A return spring 86 is supported by the turning shaft 84. The return spring 86 is, for example, a torsion coil spring, and the action lever 69 is energized by the return spring 86 in the same turning direction as an energizing direction by the lock spring 85

As described above, in the first lock mechanism 66 and the second lock mechanism 67, turning fulcrums of the action lever 69 and the lock lever 70 are set to the same turning shaft 84. Therefore, the action lever 69 and the lock lever 70 are turned about the same turning shaft 84 as a fulcrum, and the structure of the blade opening and closing device 11 can be simplified and downsized.

Furthermore, as described above, the first magnetic drive unit 16 and the second magnetic drive unit 17 are arranged in the first arrangement portion 15 a and the second arrangement portion 15 b of the housing case 15 in the up-down symmetric (line-symmetric) state, and the first lock mechanism 66 and the second lock mechanism 67 are arranged in the point-symmetric state in the up-down direction (see FIG. 16).

Specifically, the magnets 30 and 30 of the first magnetic drive unit 16 and the second magnetic drive unit 17 are arranged at the positions close to the third arrangement portion 15 c, and the coils 31 and 31 are respectively arranged in the upper and lower end portions of the housing case 15. Note that the drive lever 40 operated by the first magnetic drive unit 16 is formed in a shape in which the arm plate 42 extends in one direction, and the drive lever 40 operated by the second magnetic drive unit 17 is formed in a shape in which the arm plate 42 is bent. The difference between the shapes corresponds to the difference between an operation locus of the first opening and closing blade 19 and the operation locus of the second opening and closing blade 20, and functions and configurations of the drive levers 40 and 40 are the same.

Furthermore, in the blade opening and closing device 11, a part of the first lock mechanism 66 and a part of the second lock mechanism 67 are located to overlap in the front-rear direction that is the direction orthogonal to the up-down direction that is the arranging direction of the first magnetic drive unit 16 and the second magnetic drive unit 17 (see FIG. 27). Specifically, a part of the attracting body 68 in the first magnetic drive unit 16 is located on the rear side of the action lever 69 and the lock lever 70 in the second magnetic drive unit 17, and a part of the attracting body 68 in the second magnetic drive unit 17 is located at the rear side of the action lever 69 and the lock lever 70 in the first magnetic drive unit 16.

Note that the attracting body 68, the action lever 69, and the lock lever 70 of the first lock mechanism 66 are provided as a first attracting body, a first action lever, and a first lock lever, and the attracting body 68, the action lever 69, and the lock lever 70 of the second lock mechanism 67 are provided as a second attracting body, a second action lever, and a second lock lever

As described above, in the blade opening and closing device 11, the first magnetic drive unit 16 and the second magnetic drive unit 17 are arranged in the line-symmetric arrangement state.

Therefore, since the arrangement state of the first magnetic drive unit 16 and the second magnetic drive unit 17 is simplified, and the combined arrangement space for the first magnetic drive unit 16 and the second magnetic drive unit 17 is minimized, the first magnetic drive unit 16 and the second magnetic drive unit 17 can be easily assembled to the housing case 15, and the blade opening and closing device 11 can be downsized.

Furthermore, in the blade opening and closing device 11, the first lock mechanism 66 and the second lock mechanism 67 are located in the point-symmetric arrangement state.

Therefore, since the arrangement state of the first lock mechanism 66 and the second lock mechanism 67 is simplified, and the combined arrangement space for the first lock mechanism 66 and the second lock mechanism 67 is minimized, the first lock mechanism 66 and the second lock mechanism 67 can be easily assembled to the housing case 15, and the blade opening and closing device 11 can be further downsized.

Moreover, in the blade opening and closing device 11, the force amount adjusting parts 58 and 58 and the effective range adjusting parts 59 and 59 are located in the line-symmetric or point-symmetric arrangement state (see FIG. 22).

Therefore, since the arrangement state of the force amount adjusting parts 58 and 58 and the effective range adjusting parts 59 and 59 is simplified, and the combined arrangement space for the force amount adjusting parts 58 and 58 and the effective range adjusting parts 59 and 59 is minimized, the force amount adjusting parts 58 and 58 and the effective range adjusting parts 59 and 59 can be easily assembled to the covers 18, and the blade opening and closing device 11 can be further downsized.

Furthermore, in the blade opening and closing device 11, since the parts constituting the first lock mechanism 66 and the parts constituting the second lock mechanism 67 are the same parts, the parts constituting the first lock mechanism 66 and the parts constituting the second lock mechanism 67 can be made common. Therefore, the manufacturing cost of the blade opening and closing device 11 can be reduced.

The first link 21 and the second link 22 are respectively connected to the first opening and closing blade 19 and the second opening and closing blade 20, and the first opening and closing blade 19 and the second opening and closing blade 20 are respectively connected to the connecting shafts 44 and 44 and the rotation shafts 46 and 46 of the first magnetic drive unit 16 and the second magnetic drive unit 17 via the first link 21 and the second link 22 (see FIG. 4). Both the first link 21 and the second link 22 are parallel links.

The first link 21 includes first arms 87 and 88 located spaced in the up-down direction, and a connecting hole 87 a extending in a predetermined direction is formed in the first arm 87. The first link 21 is connected to the drive lever 40 by the connecting shaft 44 of the first magnetic drive unit 16 being slidably inserted into the connecting hole 87 a of the first arm 87. One end portions of the first arms 87 and 88 are turnably connected to the base body 13. Note that the rotation shaft 46 inserted in one of the shaft insertion holes 24 a of the base body 13 is inserted into one end portion of the first arm 87, and the first arm 87 is turned about the rotation shaft 46 as a fulcrum.

The second link 22 includes second arms 89 and 90 located spaced in the up-down direction, and a connecting hole 89 a extending in a predetermined direction is formed in the second arm 89. The second link 22 is connected to the drive lever 40 by the connecting shaft 44 of the second magnetic drive unit 17 being slidably inserted into the connecting hole 89 a of the second arm 89. One end portions of the second arms 89 and 90 are turnably connected to the base body 13. Note that the rotation shaft 46 inserted in the other shaft insertion hole 24 a of the base body 13 is inserted into one end portion of the second arm 89, and the second arm 89 is turned about the rotation shaft 46 as a fulcrum.

The first opening and closing blade 19 includes a plurality of sheet-like first sectors 91, 91, and 91. In the first opening and closing blade 19, at least parts of the first sectors 91, 91, and 91 are located to overlap in a thickness direction, and are moved between the open position where the opening 13 a of the base body 13 is opened and the closed position where the opening 13 a is closed.

One end portions of the first sectors 91, 91, and 91 are turnably connected to portions of the first arms 87 and 88. Therefore, when the magnet 30 of the first magnetic drive unit 16 is rotated, the first arms 87 and 88 are moved while maintaining the parallel state with the rotation of the magnet 30, and the first sectors 91, 91, and 91 are moved in an approximately up-down direction with the movement of the first arms 87 and 88. At this time, the first sectors 91, 91, and 91 have different moving amounts in the approximately up-down direction, and overlapping areas vary.

The second opening and closing blade 20 includes a plurality of sheet-like second sectors 92, 92, and 92. In the second opening and closing blade 20, at least parts of the second sectors 92, 92, and 92 are located to overlap in the thickness direction, and are moved between the open position where the opening 13 a of the base body 13 is opened and the closed position where the opening 13 a is closed.

One end portions of the second sectors 92, 92, and 92 are turnably connected to portions of the second arms 89 and 90. Therefore, when the magnet 30 of the second magnetic drive unit 17 is rotated, the second arms 89 and 90 are moved while maintaining the parallel state with the rotation of the magnet 30, and the second sectors 92, 92, and 92 are moved in an approximately up-down direction with the movement of the second arms 89 and 90. At this time, the second sectors 92, 92, and 92 have different moving amounts in the approximately up-down direction, and overlapping areas vary.

As described above, when the first opening and closing blade 19 and the second opening and closing blade 20 are moved, the overlapping areas vary according to the positions to which the first sectors 91, 91, and 91 and the second sectors 92, 92, and 92 are moved, and the area becomes the smallest at the open position where the opening 13 a is opened.

Therefore, the arrangement space of the first opening and closing blade 19 and the second opening and closing blade 20 becomes the small at the open position, and the area of the first opening and closing blade 19 and the second opening and closing blade 20 becomes the largest at the closed position. Therefore, the blade opening and closing device 11 can be downsized in the moving direction of the first opening and closing blade 19 and the second opening and closing blade 20, and the sufficiently large opening 13 a can be formed.

A first sheet (not illustrated) is arranged between the first opening and closing blade 19 and the second opening and closing blade 20. A contact between the first opening and closing blade 19 and the second opening and closing blade 20 is prevented and smooth operation of the first opening and closing blade 19 and the second opening and closing blade 20 is achieved by the first sheet.

Furthermore, a second sheet (not illustrated) is arranged between the second opening and closing blade 20 and the pressing plate 14, and smooth operation of the second opening and closing blade 20 is achieved by the second sheet.

[Operation of Blade Opening and Closing Device]

Hereinafter, a lock operation and the like in the blade opening and closing device 11 will be described. Note that, since the lock operations regarding the first opening and closing blade 19 and the second opening and closing blade 20 are similar, hereinafter, only the lock operation regarding the first opening and closing blade 19 will be described in detail, and detailed description of the lock operation regarding the second opening and closing blade 20 is omitted.

First, an initial state of the first opening and closing blade 19 and the second opening and closing blade 20 will be described (see FIG. 28).

In the state before the power button 6 of the imaging apparatus 1 is operated, no electric conduction is performed for the coils 31 and 31, and for example, the first opening and closing blade 19 is held at the closed position and the second opening and closing blade 20 is held at the open position. Therefore, the opening 13 a of the base body 13 is closed by the first opening and closing blade 19.

At this time, the first opening and closing blade 19 is locked as follows at the closed position (see FIG. 29).

The portion to be attracted 79 supported by the action lever 69 via the compression coil spring 78 is attracted by an attracting portion 68 b with the magnetic flux in the lock yoke 71 by the lock magnet 72, and the action lever 69 is held in a vertically extending state.

In the lock spring 85, the first arm 85 b is engaged with the spring bearing 70 c of the lock lever 70, and the second arm 85 c is engaged with the second portion 75 b of the action protrusion 75 in the action lever 69. Therefore, the action lever 69 and the lock lever 70 are energized by the energizing force of the lock spring 85 in the opposite direction with the turning shaft 84 as a fulcrum, and the pressing protrusion 76 of the action lever 69 is engaged with the extending portion 70 a of the lock lever 70 from the magnet 30 side.

The lock lever 70 is energized in a direction in which the extending portion 70 a approaches the magnet 30 by the energizing force of the lock spring 85 and is at a locked position, and the lock protrusion 70 b is engaged with the first engagement portion 43 a of the engagement piece 43 in the drive lever 40.

The lock protrusion 70 b is engaged with the first engagement portion 43 a in this way, the rotation of the drive lever 40 and the magnet 30 is restricted, and the first opening and closing blade 19 is locked at the closed position.

At this time, in the power assist spring 55, the first arm 55 b is engaged with the spring pressing portion 61 of the force amount adjusting part 58, and the second arm 55 c is engaged with the spring bearing edge 39 a of the spring bearing member 36 (see FIG. 30). Therefore, an energizing force in a direction in which the first engagement portion 43 a is pressed against the lock protrusion 70 b is provided to the drive lever 40 by the power assist spring 55. At this time, the second arm 55 c is not engaged with the spring pressing portion 63 of the effective range adjusting part 59.

When the electric conduction is performed for the coil 31 in the state where the first opening and closing blade 19 is locked at the closed position as described above, the magnetic flux generated in the first magnetic drive unit 16 provides a rotational force to the magnet 30. At this time, the energizing force in the rotating direction is provided to the drive lever 40 by the power assist spring 55. Therefore, the provided energizing force acts as assist power to the rotation of the drive lever 40.

When the electric conduction is performed for the coil 31, electric conduction is performed for the lock coil 73 at approximately the same time. When the electric conduction is performed for the lock coil 73, a magnetic flux is generated in an opposite direction to the magnetic flux in the lock yoke 71 by the lock magnet 72 and the magnetic flux in the lock yoke 71 decreases, and an attracting force of the attracting portion 68 b to the portion to be attracted 79 decreases relative to the energizing force of the return spring 86. Therefore, the action lever 69 is turned in a direction in which the second portion 75 a is away from the attracting body 68 (see FIG. 31). The action lever 69 is turned to a position where the roller 82 comes close to or comes in contact with the lever mounting member 33.

When the action lever 69 is turned, the lock lever 70 is pressed by the pressing protrusion 76 of the action lever 69, the lock lever 70 is turned from the locked position to an unlocked position, and the lock protrusion 70 b is separated from the first engagement portion 43 a of the engagement piece 43, and the engagement is released.

At this time, the rotational force is provided to the magnet 30 by the electric conduction to the coil 31, and the assist power by the power assist spring 55 is generated. Therefore, the drive lever 40 is integrally turned with the magnet 30 by combined power of the rotational force of the magnet 30 and the assist power by the power assist spring 55. Therefore, the first opening and closing blade 19 is moved from the closed position to the open position at a high speed.

When the magnet 30 and the drive lever 40 are rotated at a fixed angle, the first arm 55 b comes in contact with the spring pressing portion 63 of the effective range adjusting part 59, the second arm 55 c is separated from the spring bearing edge 39 a, and the first arm 55 b and the second arm 55 c are not engaged with the first spring bearing edge 38 a and the second spring bearing edge 39 a in the power assist spring 55 (see FIG. 32). Therefore, the energizing force is not provided from the power assist spring 55 to the drive lever 40.

When the magnet 30 and the drive lever 40 are integrally rotated, the lock lever 70 is energized in the direction of approaching the magnet 30 by the lock spring 85, and the lock protrusion 70 b, the engagement of which with the first engagement portion 43 a of the engagement piece 43 has been released, is slid on the sliding portion 43 c of the engagement piece 43 (see FIG. 33).

Furthermore, after the lock with the drive lever 40 by the lock lever 70 is released, in the middle of the magnet 30 and the drive lever 40 being integrally rotated, the electric conduction to the lock coil 73 is stopped. When the electric conduction to the lock coil 73 is stopped, the magnetic flux by the electric conduction to the lock coil 73 disappears, and the magnetic flux in the lock yoke 71 by the lock magnet 72 is recovered. Therefore, the attracting force of the attracting portion 68 a in the attracting body 68 to the portion to be attracted 79 becomes large.

When the magnet 30 and the drive lever 40 is further integrally rotated, the roller 82 supported by the action lever 69 is pressed by the pressing protrusion 34 b of the lever mounting member 33 (see FIG. 34). When the roller 82 is pressed by the pressing protrusion 34 b, the action lever 69 is turned in the direction in which the second portion 75 b approaches the attracting portion 68 b of the attracting body 68.

At this time, the electric conduction to the lock coil 73 is cancelled and the magnetic flux in the lock yoke 71 is recovered. Therefore, the portion to be attracted 79 is attracted by the attracting portion 68 a of the attracting body 68, and the action lever 69 is turned and held again in the vertically extending state. Since the lock lever 70 is energized in the direction of approaching the magnet 30 by the lock spring 85, the lock protrusion 70 b is slid on the sliding portion 43 c of the engagement piece 43.

When the magnet 30 and the drive lever 40 are integrally rotated and the action lever 69 is turned in the direction of being the vertically extending state, the first spring bearing edge 38 a of the spring bearing member 36 comes in contact with the first arm 55 b of the power assist spring 55 at the same time (see FIG. 35). At this time, the second arm 55 c of the power assist spring 55 is in contact with the spring pressing portion 63 of the effective range adjusting part 59. Therefore, the first arm 55 b is pressed in a direction of approaching the second arm 55 c by the first spring bearing edge 38 a with the rotation of the magnet 30. Therefore, the energizing force in the opposite direction to the rotation direction is provided from the power assist spring 55 to the magnet 30 and the drive lever 40. The magnet 30 and the drive lever 40 are decelerated by the energizing force in the opposite direction to the rotation direction, and this energizing force acts on the drive lever 40 and the magnet 30 as the assist power in the decelerating direction.

When the magnet 30 and the drive lever 40 are further rotated, the sliding of the lock protrusion 70 b of the lock lever 70 with respect to the sliding portion 43 c is released by the rotation of the drive lever 40, and the lock lever 70 is turned in the direction of approaching the magnet 30 by the energizing force of the lock spring 85 and reaches the locked position again from the unlocked position (see FIG. 36). When the lock lever 70 is turned, the lock protrusion 70 b is engaged with the second engagement portion 43 b of the engagement piece 43. When the lock protrusion 70 b is engaged with the second engagement portion 43 b, the electric conduction to the coil 31 is stopped and the rotation of the magnet 30 and the drive lever 40 is stopped.

When the lock protrusion 70 b of the lock lever 70 is engaged with the second engagement portion 43 b, rotation of the magnet 30 in the opposite direction to the above direction is restricted. At this time, the first opening and closing blade 19 is moved to the open position and is locked at the open position.

During a period from immediately before the first opening and closing blade 19 is moved to the open position to when moved to the open position, the energizing force of the power assist spring 55 acts on the drive lever 40 and the magnet 30 as the assist power in the decelerating direction, as described above. Therefore, the first opening and closing blade 19 is decelerated during the period from immediately before the first opening and closing blade 19 is moved to the open position to when moved to the open position

Note that, in the above description, the lock operation regarding the first opening and closing blade 19 has been described. However, as for the second opening and closing blade 20, a locked state is set at the closed position or the open position according to a similar operation to the above operation.

Meanwhile, when the magnet 30 is rotated in the opposite direction and the first opening and closing blade 19 is moved toward the closed position in the state where the first opening and closing blade 19 is in the open position, the portion to be attracted 79, the action lever 69, and the lock lever 70 are operated similarly to the above operation, engagement of the lock protrusion 70 b with the second engagement portion 43 b is released, next, the lock protrusion 70 b is slid on the sliding portion 43 c, and then the lock protrusion 70 b is engaged with the first engagement portion 43 a.

At the start of the rotation of the magnet 30 in the opposite direction, the second arm 55 c of the power assist spring 55 comes in contact with the spring pressing portion 63 of the effective range adjusting part 59, and the first arm 55 b is pressed in the direction of approaching the second arm 55 c by the first spring bearing edge 38 a (see FIG. 35). Therefore, at a predetermined rotation position immediately after the start from the start of the rotation of the magnet 30 in the opposite direction, the rotational force in the same direction as the rotation of the magnet 30 in the opposite direction is provided to the drive lever 40 by the power assist spring 55, and a large torque is provided to the magnet 30.

Furthermore, from a predetermined rotation position before the stop of the rotation of the magnet 30 in the opposite direction to a stop position, the first arm 55 b of the power assist spring 55 comes in contact with the spring pressing portion 61 of the force amount adjusting part 58, and the second arm 55 c is pressed in the direction of approaching the first arm 55 b by the second spring bearing edge 39 a. Therefore, from the predetermined rotation position before the stop of the rotation of the magnet 30 in the opposite direction to the stop position, the rotational force in the opposite direction to the rotation of the magnet 30 in the opposite direction is provided to the drive lever 40 by the power assist spring 55, and the magnet 30 and the drive lever 40 are decelerated.

As described above, the magnet 30 and the drive lever 40 are energized in the operation direction by the power assist spring 55 from the start position of the operation to a predetermined operation position after the start of the operation, and the rotational force in the same direction as the rotation of the magnet 30 is provided to the drive lever 40 by the power assist spring 55, and a large torque to the magnet 30 is provided.

Therefore, a torque in a predetermined rotation direction is provided to the drive lever 40 and the magnet 30 by the power assist spring 55, and operation speed of the first opening and closing blade 19 and the second opening and closing blade 20 can be improved.

Furthermore, a current amount to be supplied to the coil 31 can be controlled according to the force amount (spring force) of the power assist spring 55, and the operation speed of the first opening and closing blade 19 and the second opening and closing blade 20 can be set to a desired speed while reducing the power control.

Moreover, the drive lever 40 is energized in the operation direction by the power assist spring 55 from the start position of the operation to a predetermined operation position after the start of the operation, and is energized in the opposite direction to the operation direction by the power assist spring 55 from a predetermined operation position before the end of the operation to the end position of the operation.

Therefore, separate power assist springs for energizing the drive lever 40 in the opposite direction are unnecessary, and the functionality of the blade opening and closing device 11 can be improved while reducing the number of parts.

Furthermore, in the blade opening and closing device 11, the power assist spring 55 is located on the opposite side of the drive lever 40 across the magnet 30.

Therefore, since the drive lever 40 for operating the first opening and closing blade 19 or the second opening and closing blade 20 and the power assist spring 55 for providing the energizing force in the operation direction to the drive lever 40 are located on the opposite side to each other across the magnet 30, the power assist spring 55 and the drive lever 40 do not interfere and the degree of freedom of the arrangement positions of the power assist spring 55 and the drive lever 40 becomes high, and the blade opening and closing device 11 can be downsized while securing favorable functionality by the power assist spring 55.

Furthermore, since the rotation shaft 46 of the magnet 30 is located inside the external shape of the power assist spring 55, the magnet 30 and the power assist spring 55 are located side by side in the axial direction of the rotation shaft 46, and the blade opening and closing device 11 can be downsized in the direction orthogonal to the rotation shaft 46.

Moreover, since the torsion coil spring is used as the power assist spring 55, and the coil part 55 a of the power assist spring 55 is located on an inside with respect to the outer peripheral surface of the magnet 30, the coil part 55 a does not protrude outside the outer peripheral surface of the magnet 30, and the blade opening and closing device 11 can be further downsized in the direction orthogonal to the rotation shaft 46.

Furthermore, since the blade opening and closing device 11 is provided with the spring support member 53 for supporting the power assist spring 55, and the spring support member 53 is inserted in the coil part 55 a, the power assist spring 55 is supported by the spring support member 53 in the state where the spring support member 53 is located inside the coil part 55 a, and the blade opening and closing device 11 in the direction orthogonal to the rotation shaft 46 can be downsized while securing the stable supporting state of the power assist spring 55.

Furthermore, the blade opening and closing device 11 is provided with the spring bearing member 36 for receiving the first arm 55 b and the second arm 55 c of the power assist spring 55, and the spring bearing member 36 is mounted to one end surface (rear surface) of the magnet 30 in the axial direction of the rotation shaft 46 and is located on an inside with respect to the outer peripheral surface of the magnet 30.

Therefore, since the spring bearing member 36 receives the first arm 55 b and the second arm 55 c in the state of being located on an inside with respect to the outer peripheral surface of the magnet 30, the blade opening and closing device 11 in the direction orthogonal to the rotation shaft 46 can be downsized.

Moreover, since the magnet 30 and the spring bearing member 36 are integrally rotated, the spring bearing member 36 and the magnet 30 are rotated in the same direction at the same time, and the reliability of the operation of the spring bearing member 36 can be improved.

Note that the spring bearing member 36 and the magnet 30 may be formed by integral such as insert molding. In this case, a structure in which the spring bearing member 36 and the magnet 30 are integrated is formed, and thus high positioning accuracy is secured between the spring bearing member 36 and the magnet 30, and the molding accuracy of the spring bearing member 36 and the magnet 30 can be improved.

Furthermore, in the blade opening and closing device 11, the drive lever 40 is provided with the engagement piece 43 that functions as the portion to be locked, and the lock lever 70 that functions as the lock part is moved between the locked position where the locked state is set and the unlocked position where the locked state is released according to change in magnetic force with the rotation of the magnet 30.

Therefore, since the lock part and the portion to be locked are operated by the first magnetic drive unit 16 or the second magnetic drive unit 17, separate drive units for operating the lock part and the portion to be locked are not necessary, and the first opening and closing blade 19 and the second opening and closing blade 20 can be locked while simplifying the structure.

Moreover, the first opening and closing blade 19 and the second opening and closing blade 20 are moved between the open position where the opening 13 a of the base body 13 is opened and the closed position where the opening 13 a is closed, and the locked states are set at the open position and the closed position.

Therefore, the first opening and closing blade 19 and the second opening and closing blade 20 are locked at the two positions of the open position and the closed position by the single mechanism including the lock part and the portion to be locked, and the structure can be simplified and downsized.

Furthermore, since the first engagement portion 43 a to be engaged with the lock part at the open position and the second engagement portion 43 b to be engaged with the lock part at the closed position are formed in the engagement piece 43 that functions as the portion to be locked, the two engagement portions for locking the lock part at two positions are formed in the portion to be locked, and reduction in the number of parts and downsizing can be achieved.

In addition, since the drive lever 40 is provided with the engagement piece 43 that functions as the portion to be locked, and both edges of the engagement piece 43 are formed as the first engagement portion 43 a and the second engagement portion 43 b, the lock part is engaged with the both edges of the engagement piece 43 and is locked at the two positions, and the structure for locking the lock part at two positions can be simplified with the simple structure.

Moreover, sine the rotation fulcrums of the magnet 30 and the drive lever 40 coincide as the rotation shaft 46, the magnet 30 and the drive lever 40 are located side by side in the axial direction of the rotation shaft 46, and the structure of the blade opening and closing device 11 can be simplified and the structure of the blade opening and closing device 11 in the direction orthogonal to the axial direction of the rotation shaft 46 can be downsized.

Furthermore, since the drive lever 40 is fixed to the magnet 30 via the lever mounting member 33, the magnet 30 and the drive lever 40 are integrally rotated about the same rotation shaft 46 as a fulcrum, and the control can be facilitated, and the structure can be simplified and downsized by space saving.

Furthermore, since the drive lever 40 and the magnet 30 are turned in the same direction at the same time as the magnet 30 and the drive lever 40 are integrally rotated, the reliability of the operation of the drive lever 40 can be improved.

Moreover, in the blade opening and closing device 11, the arranging direction (up-down direction) of the first magnetic drive unit 16 and the second magnetic drive unit 17 coincides with the arranging direction of the first opening and closing blade 19 and the second opening and closing blade 20.

Therefore, since the first magnetic drive unit 16 and the second magnetic drive unit 17 are arranged in the order coinciding with the arranging direction of the first opening and closing blade 19 and the second opening and closing blade 20, the opening and closing operation of the first opening and closing blade 19 and the second opening and closing blade 20 can be easily performed while securing downsizing of the blade opening and closing device 11.

Furthermore, the arranging direction (up-down direction) of the first lock mechanism 66 and the second lock mechanism 67 coincides with the arranging direction of the first opening and closing blade 19 and the second opening and closing blade 20.

Therefore, since the first lock mechanism 66 and the second lock mechanism 67 are arranged in the order coinciding with the arranging direction of the first opening and closing blade 19 and the second opening and closing blade 20, the opening and closing operation of the first opening and closing blade 19 and the second opening and closing blade 20 can be easily performed while further securing downsizing of the blade opening and closing device 11.

As described above, in the blade opening and closing device 11, at least a part of the first lock mechanism 66 and at least a part of the second lock mechanism 67 are located between the first magnetic drive unit 16 and the second magnetic drive unit 17.

Therefore, since the first magnetic drive unit 16 and the second magnetic drive unit 17 are located on the opposite side across at least a part of the first lock mechanism 66 and at least a part of the second lock mechanism 67, the influence of the magnetic flux generated in one magnetic drive unit on the other magnetic drive unit can be decreased while securing downsizing of the blade opening and closing device 11.

Furthermore, at least a part of the second lock mechanism 67 is located between the first magnetic drive unit 16 and at least a part of the first lock mechanism 66, and at least a part of the first lock mechanism 66 is located between the second magnetic drive unit 17 and at least a part of the second lock mechanism 67.

Therefore, the first magnetic drive unit 16 and at least a part of the first lock mechanism 66 are located on the opposite side across at least a part of the second lock mechanism 67, and the second magnetic drive unit 17 and at least a part of the second lock mechanism 67 are located on the opposite side across at least a part of the first lock mechanism 66. Thereby, the operation of the first lock mechanism 66 can be less easily affected by the magnetic flux of the first magnetic drive unit 16 at the time of the operation of the first magnetic drive unit 16 and the first lock mechanism 66, and the operation of the second lock mechanism 67 can be less easily affected by the magnetic flux of the second magnetic drive unit 17 at the time of the operation of the second magnetic drive unit 17 and the second lock mechanism 67.

Moreover, in the blade opening and closing device 11, a part of the first lock mechanism 66 and a part of the second lock mechanism 67 are located to overlap and intersect in the front-rear direction that is the direction orthogonal to the up-down direction that is the arranging direction of the first magnetic drive unit 16 and the second magnetic drive unit 17.

Therefore, since the arrangement space of the first lock mechanism 66 and the second lock mechanism 67 becomes small in the arranging direction of the first magnetic drive unit 16 and the second magnetic drive unit 17, the first lock mechanism 66 and the second lock mechanism 67 can be located to be close to each other in the arranging direction of the first magnetic drive unit 16 and the second magnetic drive unit 17, and the blade opening and closing device 11 can be downsized.

Moreover, in the first lock mechanism 66, the turning shaft 84 of the action lever 69 is located between the first magnetic drive unit 16 and the attracting body 68, and in the second lock mechanism 67, the turning shaft 84 of the action lever 69 is located between the second magnetic drive unit 17 and the attracting body 68.

Therefore, since the distance between the turning shaft 84 and the attracting body 68 becomes large in the first lock mechanism 66 and the second lock mechanism 67, a holding force for the action lever 69 by the attracting body 68 can be made large, and the reliability of the operation of the first lock mechanism 66 and the second lock mechanism 67 can be improved.

In other words, the turning shaft 84 of the first lock mechanism 66 is located between the first magnetic drive unit 16 and the attracting body 68, and the turning shaft 84 of the second lock mechanism 67 is located between the second magnetic drive unit 17 and the attracting body 68, whereby the second portions 75 b and 75 b of the action levers 69 and 69 can be made long. Therefore, attracting positions of the portions to be attracted 79 and 79 by the attracting bodies 68 and 68 can be set to positions separated from the turning shafts 84 and 84, and the holding force for the action levers 69 by the attracting bodies 68 can be made large.

Furthermore, in the blade opening and closing device 11, the partition 28 is provided between the first magnetic drive unit 16, and the first lock mechanism 66 and the second lock mechanism 67, and the partition 28 is provided between the second magnetic drive unit 17, and the first lock mechanism 66 and the second lock mechanism 67, in the housing case 15.

Therefore, since the first magnetic drive unit 16 or the second magnetic drive unit 17 is partitioned from the first lock mechanism 66 or the second lock mechanism 67 by the partitions 28 and 28, the first lock mechanism 66 and the second lock mechanism 67 can be less easily affected by the magnetic flux of the first magnetic drive unit 16 or the magnetic flux of the second magnetic drive unit 17 at the time of the operation of the first magnetic drive unit 16 or the second magnetic drive unit 17.

Note that, in the above description, an example in which a part of the second lock mechanism 67 is located between the first magnetic drive unit 16 and the first lock mechanism 66, and a part of the first lock mechanism 66 is located between the second magnetic drive unit 17 and the second lock mechanism 67 has been described. However, a part of the first lock mechanism 66 may be located on the first magnetic drive unit 16 side, and a part of the second lock mechanism 67 may be located on the second magnetic drive unit 17 (see FIG. 37).

With such a configuration, the action lever 69 in the longitudinal direction can be made short. Therefore, the action lever 69 becomes small in weight, and the blade opening and closing device 11 can be reduced in weight.

[Operation Example of Opening and Closing Blades]

Hereinafter, an example of a specific operation of the first opening and closing blade 19 and the second opening and closing blade 20 will be described.

In the state where the power button 6 of the imaging apparatus 1 is not operated, the first opening and closing blade 19 is set to the closed position, and the second opening and closing blade 20 is set to the open position, as described above (see FIG. 28).

When the power button 6 of the imaging apparatus 1 is operated, a live view mode in which a photographer can visually recognize an object with the display 7 or the finder 9 is set, for example. At this time, a drive current is supplied to the coil 31 of the first magnetic drive unit 16, a drive force is generated in the first magnetic drive unit 16, and the first opening and closing blade 19 is moved from the closed position to the open position (see FIG. 38).

When the first opening and closing blade 19 is moved to the open position, the opening 13 a is opened and light taken in from the optical system 10 becomes incident on the imaging element 12, and the photographer can visually recognize the object with the display 7 or the finder 9.

Next, when the shutter button 4 is operated and the object is captured, the drive current is supplied to the coil 31 of the second magnetic drive unit 17, the drive force is generated in the second magnetic drive unit 17, the second opening and closing blade 20 is moved from the open position to the closed position, and the opening 13 a is closed (see FIG. 39).

When the second opening and closing blade 20 is moved to the closed position, the drive current in the opposite direction is supplied to the coil 31 of the second magnetic drive unit 17, and the second opening and closing blade 20 is moved from the closed position to the open position. When the second opening and closing blade 20 is moved toward the open position, the drive current in the opposite direction is supplied to the coil 31 of the first magnetic drive unit 16 immediately after the start of the movement of the second opening and closing blade 20 toward the open position, and the first opening and closing blade 19 is move following the second opening and closing blade 20 from the open position to the closed position. When the first opening and closing blade 19 is moved following the second opening and closing blade 20, a slit 93 having a predetermined width is formed between the second opening and closing blade 20 and the first opening and closing blade 19 (see FIG. 40), and the second opening and closing blade 20 and the first opening and closing blade 19 are moved to the open position or the closed position in the state where the slit 93 having a fixed width is formed.

The operation in which the second opening and closing blade 20 and the first opening and closing blade 19 are moved in the state where the slit 93 is formed is an operation referred to as slit traveling, and light sequentially enters the imaging element 12 from one end portion to the other end portion through the transmission hole 14 a of the pressing plate 14, the slit 93, and the opening 13 a of the base body 13 by the slit traveling, and exposure is performed.

When the slit traveling is terminated, the second opening and closing blade 20 is moved to the open position and the first opening and closing blade 19 is moved to the closed position, and the opening 13 a is closed again (see FIG. 28).

Next, the drive current is supplied to the coil 31 of the second magnetic drive unit 17, the second opening and closing blade 20 is moved to the closed position, and the opening 13 a is closed by the second opening and closing blade 20 and the first opening and closing blade 19 (see FIG. 35). In the state where the opening 13 a is closed by the second opening and closing blade 20 and the first opening and closing blade 19, the light having entered the imaging element 12 is sequentially photoelectrically converted and an image signal is generated at the time of the slit traveling, and the generated image signal is transferred to a memory and an image of the object is generated.

Note that the operation in which the light having entered the imaging element 12 is sequentially photoelectrically converted and the image signal is transferred to the memory at the time of the slit traveling may be performed in the state where the second opening and closing blade 20 is moved to the open position and the first opening and closing blade 19 is moved to the closed position, and the opening 13 a is closed when the slit traveling is terminated (see FIG. 28).

[Adjustment of Power Assist Spring]

Hereinafter, adjustment by the force amount adjusting part 58 and the effective range adjusting part 59 of the power assist spring 55 will be described (see FIGS. 42 to 45).

As described above, the force amount adjusting part 58 and the effective range adjusting part 59 are turnably supported by the first pressing surface part 56 of the cover 18. The set screws 65 and 65 are respectively inserted into the lever stop holes 56 c and 56 c and screwed with the position adjustment screw hole 60 a and the position adjustment screw hole 62 a, so that the force amount adjusting part 58 and the effective range adjusting part 59 are held at desired turning positions with respect to the first pressing surface part 56. At this time, a jig or the like (not illustrated) is inserted through the working hole 56 d into the first pressing surface part 56, and the first arm 55 b or the second arm 55 c of the power assist spring 55 can be displaced by the jig or the like, for example, to be in a non-contact state with the force amount adjusting part 58, the effective range adjusting part 59, the first spring bearing protrusion 38 of the spring bearing member 36, or the second spring bearing protrusion 39 of the spring bearing member 36.

As described above, the first arm 55 b or the second arm 55 c is made in a non-contact state with the force amount adjusting part 58, the effective range adjusting part 59, the first spring bearing protrusion 38, or the second spring bearing protrusion 39, so that adjustment by the force amount adjusting part 58 or the effective range adjusting part 59 becomes possible in a state where no energizing force of the power assist spring 56 is provided to the force amount adjusting part 58, the effective range adjusting part 59, or the spring bearing member 36, and the turning position of the force amount adjusting part 58 or the effective range adjusting part 59 can be easily set with high accuracy.

As described above, in the blade opening and closing device 11, the working hole 56 d for performing adjustment regarding the energizing force of the power assist spring 55 is formed in the cover 18.

Therefore, the adjustment regarding the energizing force of the power assist spring 55 can be performed through the working hole 56 d in a state where each part such as the cover 18 is assembled in the housing case 15, and the adjustment regarding the energizing force of the power assist spring 55 can be appropriately and easily performed in the assembled state of the each part.

In the adjustment by the force amount adjusting part 58, the force amount adjusting part 58 is turned to a desired position in the state where the first arm 55 b of the power assist spring 55 is in contact with the spring pressing portion 61 of the force amount adjusting part 58 and the second arm 55 c of the power assist spring 55 is pressed by the second spring bearing edge 39 a of the spring bearing member 36 (see FIG. 42), for example, so that the energizing force (force amount) of the power assist spring 55 to the magnet 30 and the drive lever 40 can be changed (see FIG. 43).

As described above, the blade opening and closing device 11 is provided with the force amount adjusting part 58 for adjusting the energizing force of the power assist spring 55.

Therefore, since the energizing force of the power assist spring 55 can be adjusted by the force amount adjusting part 58, a desired energizing force is provided to the drive lever 40 from the power assist spring 55 regardless of variations of the energizing force due to the processing accuracy of the power assist spring 55, the assembly accuracy of each part, or the like, and the first opening and closing blade 19 and the second opening and closing blade 20 can be operated at a desired speed.

In the adjustment by the effective range adjusting part 59, the effective range adjusting part 59 is turned to a desired position in the state where the first arm 55 b of the power assist spring 55 is in contact with the spring pressing portion 61 of the force amount adjusting part 58, and the second arm 55 c of the power assist spring 55 is in contact with the spring pressing portion 63 of the effective range adjusting part 59 (see FIG. 44), for example, whereby the range (angle) of generation of the energizing force of the power assist spring 55 to the magnet 30 and the drive lever 40 can be changed (see FIG. 45).

For example, the position of the second arm 55 c of the power assist spring 55 corresponding to an operation start position (traveling start position of the opening and closing blade) is defined as position P1 (see FIGS. 42, 44, and 45), the position of the second arm 55 c before adjustment is defined as position P2 (see FIG. 44), and the position of the second arm 55 c after adjustment is defined as position P3 (see FIG. 45). The range in which the energizing force for the magnet 30 and the drive lever 40 by the power assist spring 55 is generated is an operation range R1 of P1 and P2 before adjustment (see FIG. 44), and an operation range R2 of P1 and P3 after adjustment (see FIG. 45).

As described above, the blade opening and closing device 11 is provided with the effective range adjusting part 59 for adjusting the range in which the energizing force of the power assist spring 55 is provided.

Therefore, since the range in which the energizing force of the power assist spring 55 is provided can be adjusted by the effective range adjusting part 59, the energizing force is provided from the power assist spring 55 to the drive lever 40 in a desired range regardless of variations of the range of the energizing force due to the processing accuracy of the power assist spring 55, the assembly accuracy of each part, or the like, and the first opening and closing blade 19 and the second opening and closing blade 20 can be operated at a desired speed.

Furthermore, the blade opening and closing device 11 is provided with the cover 18 that covers the magnet 30 and the power assist spring 55, and the force amount adjusting part 58 and the effective range adjusting part 59 are supported on the inner surface side of the cover 18.

Therefore, since the magnet 30 and the power assist spring 55 are covered with the cover 18, and the force amount adjusting part 58 and the effective range adjusting part 59 are supported by the cover 18, special parts for supporting the force amount adjusting part 58 and the effective range adjusting part 59 are not necessary, and the magnet 30 and the power assist spring 55 can be protected and the force amount adjusting part 58 and the effective range adjusting part 59 can be supported while decreasing the number of parts.

Note that the positions of the force amount adjusting part 58 and the effective range adjusting part 59 may be located in the opposite direction to the above description in the right-left direction.

Moreover, since the power assist spring 55 is located between the force amount adjusting part 58 and the effective range adjusting part 59, the force amount adjusting part 58 and the effective range adjusting part 59 are located on the opposite side to each other across the power assist spring 55, the force amount adjusting part 58 and the effective range adjusting part 59 do not interfere, and the adjustment by the force amount adjusting part 58 and the effective range adjusting part 59 with respect to the power assist spring 55 can be easily and reliably performed.

Furthermore, the force amount adjusting part 58 is turnably supported by the cover 18, and energizing force of the power assist spring 55 is changed according to the turning position of the force amount adjusting part 58 with respect to the cover 18.

Therefore, the energizing force provided from the power assist spring 55 to the drive lever 40 is changed as the force amount adjusting part 58 is turned with respect to the cover 18, and thus the adjustment of the energizing force by the force amount adjusting part 58 can be easily performed.

In addition, the effective range adjusting part 59 is turnably supported by the cover 18, and the range of the energizing force provided from the power assist spring 55 to the drive lever 40 is changed according to the turning position of the effective range adjusting part 59 with respect to the cover 18.

Therefore, the range of the energizing force provided from the power assist spring 55 to the drive lever 40 is changed as the effective range adjusting part 59 is turned with respect to the cover 18, and thus the adjustment of the energizing force by the effective range adjusting part 59 can be easily performed.

[Others]

In the blade opening and closing device 11, when the lock protrusion 70 b of the lock lever 70 is slid on the sliding portion 43 c of the engagement piece 43 at the time of the turning of the drive lever 40, a sound due to sliding (shutter sound) may occur, and the occurring sound may become an abnormal sound. Therefore, to reduce or prevent the occurrence of sound due to sliding or to change the tone, the timing of the turning of the lock lever 70 relative to the drive lever 40 may be changed, or the material of the lock lever 70 or the engagement piece 43 may be changed, for example.

<2. Control Configuration of Imaging Apparatus>

FIG. 46 illustrates a control configuration of the imaging apparatus 1 including the blade opening and closing device 11 as described above as a mechanical shutter mechanism.

As illustrated in FIG. 46, the imaging apparatus 1 includes an imaging element unit 325 that receives incident light from an optical system (not illustrated). The imaging element unit 325 includes, for example, an imaging element of a charge coupled device (CCD) type, a complementary metal oxide semiconductor (CMOS) type, or the like, and a peripheral circuit system, and receives incident light via the blade opening and closing device 11 and converts the incident light into an electrical signal. For the electrical signal obtained by photoelectric conversion in the imaging element, for example, correlated double sampling (CDS) processing, automatic gain control (AGC) processing, and the like are executed, and analog/digital (A/D) conversion processing is further performed. Then, a captured image signal as digital data is supplied to a main control unit 301.

The main control unit 301 performs operation control of each unit of the imaging apparatus 1 and signal processing of the captured image signal. The main control unit 301 includes a microcomputer (arithmetic processing unit) provided with, for example, a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), a flash memory, and the like.

The CPU executes a program stored in the ROM, the flash memory, or the like to control the entire imaging apparatus 1 in an integrated manner.

The RAM is used for temporary storage of data, programs, and the like, as a work area for various data processing by the CPU.

The ROM and the flash memory (nonvolatile memory) are used to store an operating system (OS) for the CPU to control each unit, content files such as image files, an application program for various operations, firmware, and the like.

Note that the control function and the captured image signal processing function may be separately configured as separate chips, for example, a microcomputer a digital signal processor (DSP), and the like.

The main control unit 301 has functions as a blade opening and closing device setting unit 302, a time length setting unit 303, a current value setting unit 304, a signal processing unit 306, a recording processing unit 307, as illustrated. These functions are operation functions realized by processing executed by a program by the microcomputer, and illustrate a software configuration.

Note that the blade opening and closing device setting unit 302, the time length setting unit 303, and the current value setting unit 304 are functions particularly related to a shutter operation (curtain travel setting) of the embodiment to be described below. These functions will be described below.

The signal processing unit 306 and the recording processing unit 307 are functions as the normal imaging apparatus 1. Note that, although illustration is omitted, in practice, the main control unit 301 is assumed to have more various functions.

First, functions as the signal processing unit 306 and the recording processing unit 307 and peripheral configurations, and control processing of the main control unit 301 by functions (not illustrated) will be described.

The signal processing unit 306 applies various types of signal processing to a digital signal (captured image signal) from the imaging element unit 325.

For example, the signal processing unit 306 performs noise removal processing, color correction processing, contour enhancement processing, resolution conversion processing, codec processing, and the like for the captured image signal. Thereby, the signal processing unit 306 generates image data for recording, transmission, display, and the like, as a still image or a moving image.

The recording processing unit 307 is a function to perform control for causing a recording unit 324 to record the image data processed in the signal processing unit 306 in a recording medium. In other words, the recording processing unit 307 supplies the image data encoded for recording to the recording unit 324, provides a recording instruction and recording address information, and causes the recording unit 324 to execute a recording operation. Furthermore, the recording processing unit 307 can provide a reading instruction and reading address information to the recording unit 324 to cause the recording unit 324 to execute reading of the image data and the like from the recording medium.

The recording unit 324 stores the image data in the storage medium on the basis of the control of the main control unit 301 (recording processing unit 307). The storage medium may be a removable medium as a memory card, an optical disc, a magnetic tape, or the like, or may be a fixed-type hard disk drive (HDD), semiconductor memory module, or the like.

The main control unit 301 has a display control function as a function (not illustrated). The main control unit 301 supplies an instruction and display data to a user interface (UI) control unit 328 to cause the UI control unit 328 to execute display on a display device 327.

The display device 327 is a display unit that performs various displays for a user (imaging person), and is formed including a display device such as a liquid crystal display (LCD) or an organic electro-luminescence (EL) as the display 7 formed on the housing of the imaging apparatus 1, for example. Note that the display device 327 may be formed using an LCD, an organic EL display, or the like in the form of a so-called viewfinder.

For such a display device 327, the main control unit 301 performs control to display, for example, a so-called through image (object monitoring image) being captured or display an image reproduced by the recording unit 324.

Furthermore, the main control unit 301 instructs the UI control unit 328 to display various operation menus, icons, messages, and the like, as graphical user interface (GUI), on a screen.

Furthermore, the main control unit 301 has a function to detect operation information, and detects user operation information by an operation unit 321.

The operation unit 321 collectively shows operators and input devices for the user to perform various operation inputs. For example, operators such as the shutter button 4 (release button), the zoom switch 5, the power button 6 provided on the housing 2 of the imaging apparatus 1, other menu buttons, an enter button, a cross key, a cancel button, a mode key, and a slide key are collectively shown as the operation unit 321.

Furthermore, in a case where the display device 327 is provided with a touch panel, various operations may be made possible by a touch panel operation using icons, menus, or the like to be displayed on the display device 327, or a tap operation, a slide operation, and the like of the user may be detected by a touch pad or the like. Further, a separate remote controller may be used. These touch panel, touch pad, and remote controller are also included in the operation unit 321.

Furthermore, the main control unit 301 has a function to control the operation of the imaging element. In other words, the main control unit 301 instructs an imaging element control unit 326 to operate the imaging element in the imaging element unit 325, and controls a photoelectric conversion operation. For example, the main control unit 301 issues, to the imaging element control unit 326, an on/off instruction for the photoelectric conversion operation, a timing instruction, an electronic shutter speed setting instruction, a synchronization signal supply, and the like. The imaging element control unit 326 controls charge accumulation, transfer (read), and reset operation of the imaging element according to the instruction.

Moreover, the main control unit 301 controls focus/zoom operation, autofocus, operations of necessary units for a communication operation with an external device by a communication unit (not illustrated), and the like.

Next, curtain travel control of the blade opening and closing device 11 will be described.

The blade opening and closing device 11 includes a front curtain unit 334 and a rear curtain unit 335.

The blade opening and closing device setting unit 302 in the main control unit 301 performs setting processing of drive timing or the like of the blade opening and closing device 11. For example, the blade opening and closing device setting unit 302 performs settings related to the shutter operation of the blade opening and closing device 11 on the basis of a user operation or a program.

A blade opening and closing device control unit 329 controls the operation of the front curtain unit 334 and the rear curtain unit 335 on the basis of the setting. The front curtain unit 334 represents a mechanism related to the first opening and closing blade 19, and the rear curtain unit represents a mechanism related to the second opening and closing blade 20.

Each of the front curtain unit 334 and the rear curtain unit 335 includes an electromagnetic drive source 330, an opening and closing blade 331, a lock drive source 322, and a lock lever 333.

These elements correspond as follows in the structure of the above-described blade opening and closing device 11.

The electromagnetic drive source 330 is the first time drive unit 16 and the second time drive unit 17.

The opening and closing blade 331 is the first opening and closing blade 19 or the second opening and closing blade 20.

The lock drive source 322 is the attracting body 68.

The lock lever 333 is the lock lever 70.

The blade opening and closing device control unit 329 performs electric conduction to the electromagnetic drive source 330 and the lock drive source 322 for each of the front curtain unit 334 and the rear curtain unit 335, thereby driving the opening and closing blade 331 and the lock lever 333. Thereby, the curtain travel of the above-described opening and closing blade 331 is executed.

FIG. 47 illustrates a shutter operation signal, a motor signal, a motor current value, and an unlock signal as signal waveforms for curtain travel control in the front curtain unit 334 and the rear curtain unit 335.

The shutter operation signal is a signal indicating shutter operation timing by the user. For example, the main control unit 301 detects a rising edge of the shutter operation signal from the operation unit 321 to detect a shutter operation.

The main control unit 301 instructs the blade opening and closing device control unit 329 to drive the electromagnetic drive source 330 in response to recognition of the shutter operation timing.

The blade opening and closing device control unit 329 applies the motor signal (drive voltage) to the electromagnetic drive source 330. In response to the application of the motor signal, a current flows through the coil 31 of the electromagnetic drive source 330 according to the illustrated motor current value.

Thereafter, the blade opening and closing device control unit 329 provides the unlock signal to the electromagnetic drive source 330. As a result, the locking by the lock lever 333 is released, and the curtain travel by a motor torque and a spring torque is started.

Note that, for the sake of description, the time length of a period from supply start timing of the motor signal to supply timing of the unlock signal is represented as time length T.

Further, an upper limit value as the motor current value is defined as a current value Ar. This current value Ar is a limit value of the current value provided to the electromagnetic drive source 330. The blade opening and closing device control unit 329 maintains the state in which the current value Ar flows through the coil 31 during the curtain travel.

Regarding the curtain travel, the imaging apparatus 1 includes a durability counter 341, a drive source temperature sensor 342, a curtain speed sensor 336, and a detection value storage unit 337.

The durability counter 341 counts the number of times of curtain travel of the opening and closing blade 331. A count value of the durability counter 341 is stored in the detection value storage unit 337 in an updated state each time.

The drive source temperature sensor 342 detects the temperature of the electromagnetic drive source 330.

Information of the detected temperature is stored in the detection value storage unit 337.

The curtain speed sensor 336 detects the curtain traveling speed. Information of the detection speed is stored in the detection value storage unit 337.

As a result, the main control unit 301 can confirm the number of times of traveling, a temperature state, and a curtain speed state with reference to the detection value storage unit 337 when necessary.

The time length setting unit 303 as a function of the main control unit 301 illustrated in FIG. 46 is a function to set the time length T, in other words, a time length from the start of the electric conduction to the coil 31 to the start of traveling of the opening and closing blade 331, for correction of the curtain travel or intentional exposure effect.

Further, the current value setting unit 304 is a function to set the current value Ar, in other words, a current limit value to be supplied to the coil.

<3. Correction of Curtain Travel Curve>

The main control unit 301 can correct a curtain travel state of the blade opening and closing device 11 by the functions of the time length setting unit 303 and the current value setting unit 304. Hereinafter, curtain travel correction will be described with reference to a curtain travel curve.

FIG. 48A is a curtain travel curve illustrating the curtain travel state of the opening and closing blade 331.

The horizontal axis represents time and the vertical axis represents a curtain vertical position. In other words, the curtain vertical position is a position of each time at the time of traveling of the opening and closing blade 331 (first opening and closing blade 19 or second opening and closing blade 20).

FIG. 48B illustrates an example of a torque curve of a drive body 33. The horizontal axis represents time and the vertical axis represents a drive body torque. The dotted line and the solid line illustrate the motor torque, the broken line is the spring torque, and the one-dot chain line is the combined torque. In a period where the plurality of lines is at the same level, the lines are illustrated along the lines (similarly illustrated in FIGS. 49B and 50B to be described below).

It is assumed that the electric conduction to the coil 31 is started at time t0. The period illustrated by the dotted line from time t0 to t1 as the motor torque is a period in which the motor torque does not act on a drive body operation because the drive body 33 is in the locked state.

The lock is released at time t1, and curtain travel is started. At the time of unlock, the maximum amount of spring torque (broken line) by the power assist spring 55 is generated. In addition, the motor torque increases at and after time t1 due to an increase in current (solid line). Therefore, a moving torque of the drive body 33 becomes the combined torque (one-dot chain line) of the spring torque and the motor torque.

Time t2 is time when the spring torque disappears (time when the state in FIG. 32 is started). At and after this time t2, the drive body 33 moves by the motor torque (solid line). The motor torque is a torque corresponding to the current value Ar.

For example, the torques change as time progresses. Then, the spring mechanism of the power assist spring 55, and the motor mechanism as the electromagnetic drive source 330 by the coil 31, the magnet 30, the yoke 32, and the like are designed such that the opening and closing blade 331 travels as illustrated as the curtain travel curve in FIG. 48A by such torques.

However, the curtain running state may not be maintained in the state illustrated in FIG. 48A due to variations in spring manufacturing, aging, temperature state, and other factors.

Therefore, in the present embodiment, correction is performed to obtain the curtain travel state in FIG. 48A, for example.

As described above, the drive body 33 is given two torques of the spring torques by the power assist spring 55 and the motor torque by the electromagnetic drive source 330.

In an initial stage of traveling (time t1 to t2), the combined torque of the power assist spring 55 and the electromagnetic drive source 330 is applied to the drive body 33, but at and after time t2 where the drive body 33 travels at a fixed angle, the state becomes the state in FIG. 32 and only the motor torque of the electromagnetic drive source 330 is provided.

Here, consider adjustment of torques to be provided to the drive body 33 at the initial stage of traveling (time t1 to t2) and at or after a middle stage (at or after time t2).

First, torque correction at the initial stage of traveling will be described.

FIG. 49A illustrates an example of the curtain travel curve before correction (solid line) and a correction goal (broken line). For example, if the torque at the initial stage of traveling is insufficient, the curtain travel curve before correction is obtained. It is assumed that the curtain travel curve of the correction goal is the curtain travel curve in FIG. 48A.

Since the combined torque of the spring torque and the motor torque works at the initial stage of traveling, the torque at the initial stage of traveling becomes insufficient in a case where the power assist spring 55 is deteriorated or the spring torque is insufficient due to original manufacturing variations, for example.

Further, the torque at the initial stage of traveling becomes insufficient in a case where a blade sliding resistance at the start of traveling of the opening and closing blade 331 increases due to time-dependent causes, manufacturing variations, or the like, for example, and the curtain travel curve before correction as in FIG. 49A may be obtained.

In such a case, it is desirable to increase only the torque of at the initial stage of traveling. Therefore, the time length T from the start of the electric conduction to the electromagnetic drive source 330 to unlock is set to be long.

FIG. 49B illustrates an example in which the time length T is made long.

For example, by setting the start of the electric conduction to the coil 31 to time point t0′ (in other words, by delaying unlock timing), the time length T from the start of the electric conduction to the unlock becomes long as compared with FIG. 48B.

As a result, the lock is released in a state where the current value flowing through the coil 31 of the electromagnetic drive source 330 increases to the vicinity of the upper limit current value Ar, and the curtain travel is started.

Then, since the large motor torque is applied at the start of traveling, the combined torque (one-dot chain line) of the power assist spring 55 and the electromagnetic drive source 330 at the initial stage of traveling (time t1 to t2) rises as compared with the case of FIG. 48B.

Meanwhile, if the setting (current value Ar) as the current limit value is unchanged, the torque at or after the middle stage of traveling (at or after time t2) where the spring torque disappears is the same as the torque in FIG. 48B.

As a result, only the torque to the drive body 33 at the initial stage of traveling can be increased.

Then, the state can be corrected to obtain the curtain travel curve as in the correction goal in FIG. 49A.

That is, by setting the time value T to be long, the drive body 33 (opening and closing blade 331) starts traveling after the current (=motor torque) has fully risen, so the initial combined torque becomes large. Meanwhile, the torque outside the effective spring range is the same as that before the correction. Therefore, in the case of increasing the torque at the initial stage of traveling, it is only required to set the time length T to be long.

Conversely, in the case of decreasing only the torque at the initial stage of traveling, it is only required to set the time length T to be short.

Next, torque correction at or after the middle stage will be described.

FIG. 50A illustrates an example of the curtain travel curve before correction (solid line) and a correction goal (broken line). For example, if the torque at or after the middle stage is insufficient, the curtain travel curve before correction is obtained. It is assumed that the curtain travel curve of the correction goal is the curtain travel curve in FIG. 48A.

Since the spring torque disappears at or after the middle stage of traveling, the curtain travel curve before correction in FIG. 50A is obtained if the motor torque is insufficient. Possible causes include motor performance degradation due to temperature characteristics, increased blade sliding resistance during travel, and the like.

In such a case, it is desirable to increase only the torque of at or after the middle stage of traveling. Therefore, the setting (current limit value) of the current value Ar flowing through the coil 31 of the electromagnetic drive source 330 is increased.

FIG. 50B illustrates an example in which the current value Ar is increased. In this example, the torque at time t0 and t1 is the same as that in FIG. 48B.

As a result, since the current does not fully rise in an early stage and the current value during a period in which the current value has not reached the current value Ar is unchanged as compared with the case in FIG. 48B, the combined torque at the initial stage of traveling is unchanged.

Meanwhile, in the case of FIG. 50B, the current flowing through the coil 31 continues to rise to the increased current value Ar. Then, since the motor torque after the current has fully risen increases, the motor torque at or after the middle stage of traveling rises as compared with the case in FIG. 48B. As a result, it is possible to increase only the torque at or after the middle stage of traveling.

Then, the state can be corrected to obtain the curtain travel curve as in the correction goal in FIG. 50A.

In this way, the torque at or after the middle stage of traveling can be adjusted by the setting of the current value Ar. The torque at or after the middle stage of traveling increases by setting the current value Ar to be large, and the torque at or after the middle stage of traveling decreases by setting the current value Ar to be small.

As described above, as adjustment parameters, two parameters of the time length T from the start of the electric conduction to the unlock and the current value Ar to flow through the coil 31 are set. Then, the parameters are adjusted as follows.

-   -   The time value T is set to be long to accelerate at the initial         stage of traveling without affecting acceleration in the latter         half.     -   The setting value of the current value Ar is set to be large to         accelerate at or after the middle stage of traveling without         affecting initial acceleration.     -   The time length T is set to be long and the setting value of the         current value Ar is set to be large to accelerate at the initial         stage of traveling and at or after the middle stage of         traveling.     -   The time value T is set to be short to decelerate at the initial         stage of traveling without affecting acceleration in the latter         half.     -   The setting value of the current value Ar is set to be small to         decelerate at or after the middle stage of traveling without         affecting initial acceleration.     -   The time length T is set to be short and the setting value of         the current value Ar is set to be small to decelerate at the         initial stage of traveling and at or after the middle stage of         traveling.

In the main control unit 301, the time length setting unit 303 sets the time length T and instructs drive timing of the lock drive source 322 (=unlock timing) to the blade opening and closing device 11. As a result, the time length from the time when the blade opening and closing device control unit 329 starts current supply to the electromagnetic drive source 330 to the time of unlock changes. That is, the torque correction at the initial stage of traveling of the curtain travel is performed.

Further, in the main control unit 301, the current value setting unit 304 sets the current value Ar and the blade opening and instructs the current value Ar to the blade opening and closing device control unit 329. In response to the instruction, the blade opening and closing device control unit 329 supplies the instructed current value to the electromagnetic drive source 330. As a result, the torque correction at or after the middle stage of traveling is performed.

An example of curtain travel correction control to make the curtain travel curve appropriate by the main control unit 301 will be described with reference to FIGS. 51 and 52. FIGS. 51 and 52 illustrate a processing example mainly executed by the main control unit 301 according to the functions of the blade opening and closing device setting unit 302, the time length setting unit 303, and the current value setting unit 304.

When a power-on operation of the imaging apparatus 1 is performed by the user, the main control unit 301 performs power-on processing in step S101, and sets each unit to a state where imaging is possible.

In step S102, the main control unit 301 performs curtain travel correction necessity determination. That is, the imaging apparatus 1 determines whether or not curtain travel correction is currently necessary.

Examples of curtain travel correction necessity determination processing are shown in FIGS. 52A, 52B, and 52C.

FIG. 52A is an example of determining whether or not curtain travel correction is necessary on the basis of the number of times of traveling of the opening and closing blade 331.

In step S151, the main control unit 301 acquires a count value NC of the durability counter 341 from the detection value storage unit 337.

In step S152, the main control unit 301 then compares the count value NC with a preset number of times threshold thNC.

In the case of NC thNC, the main control unit 301 determines that the curtain travel correction is necessary in step S153, and in the case of not NC thNC, the main control unit 301 determines that the curtain travel correction is unnecessary in step S154. In other words, this is processing that determines necessity of correction after a predetermined number of times of curtain travel has been performed over time.

FIG. 52B is an example of determining whether or not curtain travel correction is necessary on the basis of the temperature state.

In step S161, the main control unit 301 acquires a temperature detection value TP of the drive source temperature sensor 342 from the detection value storage unit 337.

In step S162, the main control unit 301 then compares the temperature detection value TP with a preset temperature threshold thTP.

In the case of TP≥thTP, the main control unit 301 determines that the curtain travel correction is necessary in step S163, and in the case of not TP≥thTP, the main control unit 301 determines that the curtain travel correction is unnecessary in step S164. In other words, this is processing that determines necessity of correction when the current temperature of the electromagnetic drive source 330 is a predetermined value or higher.

Note that, in the above-described structure example, the power assist spring 55 is also arranged near the electromagnetic drive source 330, and thus the torque reduction due to the influence of the temperature on the electromagnetic drive source 330 and the power assist spring 55 is determined. It is also conceivable to determine necessity of the curtain travel correction according to the temperature detection of only the electromagnetic drive source 330 or the temperature detection of only the power assist spring 55 depending on the structure.

FIG. 52C is an example of determining whether or not curtain travel correction is necessary on the basis of a curtain speed state.

In step S171, the main control unit 301 acquires a speed detection value VS by the curtain speed sensor 336 from the detection value storage unit 337.

In step S172, the main control unit 301 then compares the temperature detection value VS with a preset speed threshold thVS.

In the case of VS≤thVS, the main control unit 301 determines that the curtain travel correction is necessary in step S173, and in the case of not VS≤thVS, the main control unit 301 determines that the curtain travel correction is unnecessary in step S174. In other words, this is processing that determines necessity of correction when the current curtain speed is a predetermined speed or lower.

Note that any one or a plurality of these determinations in FIGS. 52A, 52B, and 52C may be performed. In the case of performing a plurality of the determinations, it is conceivable to determine necessity of the curtain travel correction under an AND condition or an OR condition of the determinations. Alternatively, it is also conceivable to determine necessity of the curtain travel correction, for example, when two or more determinations require the necessity of correction after the three types of processing is performed.

Of course, other types of determination processing may be performed other than these three types of processing. For example, it is conceivable to determine the necessity of the curtain travel correction by confirming humidity, elapsed time from manufacture date, continuous use time, or the like, or employs the aforementioned elements as determination factors.

Although setting values for determining the number of times threshold thNC, the temperature threshold thTP, the speed threshold thVS, and the like may be fixed values, the setting values may be changed by the user or may be changed according to a correction history or the like.

Description will be given returning to FIG. 51.

After performing the curtain travel correction necessity determination in step S102, the main control unit 301 branches the processing according to the result of the curtain travel correction necessity determination in step S103.

In the case where the curtain travel correction is unnecessary, the main control unit 301 proceeds to step S104, and monitors a power-off operation by the user. During the period in which the power-off operation is not performed, the main control unit 301 confirms whether or not the release determination is made, in other words, whether or not the user has pressed the shutter button 4 in step S105.

In a case where the shutter operation is detected, the main control unit 301 proceeds to step S106 and performs exposure control. That is, the main control unit 301 instructs the blade opening and closing device control unit 329 to execute the curtain travel of the opening and closing blade 331 by the front curtain unit 334 and the rear curtain unit 335.

In other words, when the opening and closing blade 331 of the front curtain unit 334 travels, the opening 13 a of the base body 13 is opened (see FIG. 38), and the light from the optical system 10 reaches the imaging element (see FIG. 3). Thereafter, the opening and closing blade 331 of the rear curtain unit 335 performs a similar operation to the opening and closing blade 331 of the front curtain unit 334, so that the opening 13 a of the base body 13 is shielded from light (see FIG. 41).

After executing such curtain travel, the main control unit 301 returns to the monitoring loop of steps S104 and S105 (steps S106-S104 are illustrated as the solid line).

In the case where the curtain travel correction is necessary in the above curtain travel correction necessity determination, the main control unit 301 proceeds to step S110 from step S103 and performs correction setting.

In other words, as a result of the curtain travel correction necessity determination, the correction is required, the main control unit 301 determines what correction is to be performed, and performs processing of determining a torque correction amount.

Specifically, as a correction type, the main control unit 301 determines which of the following correction types is to be performed:

-   -   torque up correction only at the initial stage of traveling;     -   torque down correction only at the initial stage of traveling;     -   torque up correction only at or after the middle stage of         traveling;     -   torque down correction only at or after the middle stage of         traveling;     -   torque up correction at the initial stage of traveling and         torque up correction of at or after the middle stage of         traveling;     -   torque down correction at the initial stage of traveling and         torque up correction at or after the middle stage of traveling;     -   torque up correction at the initial stage of traveling and         torque down correction at or after the middle stage of         traveling; and     -   torque down correction at the initial stage of traveling and         torque down correction at or after the middle stage of         traveling.

Furthermore, the main control unit 301 determines the correction amount of torque up or torque down in each type. In other words, the correction amount is a change amount of the time length T or a change amount of the current value Ar.

It is conceivable that these determinations can be made using the count value NC of durability, the temperature detection value TP of the drive source temperature, the speed detection value VS as the current speed, or other indicators at the time of curtain travel correction necessity determination. Furthermore, for example, it is conceivable that the correction value can be obtained from a difference between the detected value and a threshold or the like. Various methods are assumed as to how to set the correction content (the correction type and the correction amount).

After performing the setting of the correction content in the correction setting in step S110, the main control unit 301 branches the processing according to whether or not to correct the torque at the initial stage of traveling in step S111.

In the case where the necessity of the initial torque correction is determined in the correction setting, the main control unit 301 proceeds to step S112 from step S111 and further proceeds to step S113 or S114 according to the up/down setting of the initial torque.

In other words, in the case where execution of the torque up correction at the initial stage of traveling is set in the correction setting, the main control unit 301 proceeds to step S113 and extends the time length T by the set correction amount.

Further, in the case where execution of the torque down correction at the initial stage of traveling is set in the correction setting, the main control unit 301 proceeds to step S114 and shortens the time length T by the set correction amount.

In step S115, the main control unit 301 branches the processing according to whether or not performing torque correction at or after the middle stage of traveling.

In the case where the correction type is “torque up correction only at the initial stage of traveling” or “torque down correction only at the initial stage of traveling” above, the torque correction at or after the middle stage of traveling is unnecessary. Therefore, the main control unit proceeds to step S104 and performs release monitoring at step S105.

In this case, when the main control unit 301 proceeds step S106 by the release detection, the main control unit 301 executes the curtain travel in the state where the torque at the initial stage of traveling is adjusted with the time length T, the setting of which has been changed. Therefore, the curtain travel is executed in the state where the time length T is extended or shortened as compared with the case of non-correction.

After executing the curtain travel, the main control unit 301 returns to the monitoring loop of steps S104 and S105. Then, the main control unit 301 proceeds to step S106 each time of the release detection, and the curtain travel is similarly executed in the state where the time length T is extended or shortened as compared with the case of no-correction.

In the case where the connection type to be executed is “torque up correction only at or after the middle stage of traveling” or “torque down correction only at or after the middle stage of traveling” in the correction setting in step S110, the main control unit 301 proceeds to step S120 from S111, and further proceeds to step S121 or S122 according to the up/down setting of the torque at or after the middle stage of traveling.

In other words, in the case where execution of the torque up correction at or after the middle stage of traveling is set in the correction setting, the main control unit 301 proceeds to step S121 and increases the current value Ar by the set correction amount.

Further, in the case where execution of the torque down correction at or after the middle stage of traveling is set in the correction setting, the main control unit 301 proceeds to step S122 and decreases the current value Ar by the set correction amount.

Then, the main control unit 301 proceeds to step S104, and performs the release monitoring in step S105. In this case, when the main control unit 301 proceeds step S106 by the release detection, the main control unit 301 executes the curtain travel in the state where the torque at or after the middle stage of traveling is adjusted with the current value Ar, the setting of which has been changed. Therefore, the curtain travel is executed in the state where the current value Ar is increased or decreased.

After executing the curtain travel, the main control unit 301 returns to the monitoring loop of steps S104 and S105. Then, the main control unit 301 proceeds to step S106 each time of the release detection, and the curtain travel is similarly executed in the state where the current value Ar is increased or decreased as compared with the case of no-correction.

In the correction setting in step S110, in the case where the correction type to be executed is any of “torque up correction at the initial stage of traveling and torque up correction of at or after the middle stage of traveling”, “torque down correction at the initial stage of traveling and torque up correction at or after the middle stage of traveling”, “torque up correction at the initial stage of traveling and torque down correction at or after the middle stage of traveling”, and “torque down correction at the initial stage of traveling and torque down correction at or after the middle stage of traveling”, the main control unit 301 extends or shortens the time length T in step S113 or S115, and then proceeds to step S120 from step S115 and increases or decreases the current value Ar in step S121 or S122.

Then, the main control unit 301 proceeds to step S104, and performs the release monitoring in step S105. In this case, in the case where the main control unit 301 proceeds to step S106 by the release detection, the curtain travel is executed in the state where the time length T is extended or shortened as compared with the case of non-correction, and the current value Ar is increased or decreased.

After executing the curtain travel, the main control unit 301 returns to the monitoring loop of steps S104 and S105. Then, the main control unit 301 proceeds to step S106 each time of the release detection, and the curtain travel is similarly executed in the state where the time length T is extended or shortened, and the current value Ar is increased or decreased, as compared with the case of no-correction.

In a case where the power-off is determined due to a termination operation of the user, passage of time without operation, or the like, the main control unit 301 proceeds to step S107 from S104, and performs power-off processing and terminates the series of control.

With the above processing, the change in the curtain travel due to manufacturing variations, aging, temperature state, and other factors can be corrected.

Note that, in the above description, the processing returns to step S104 from step S106 as illustrated as the solid line. However, according to this processing, the correction setting performed at the time of power-on is valid until power-off. In other words, the processing load for the correction necessity determination and the correction setting is small.

Meanwhile, as illustrated as the broken line in FIG. 51, the processing may return to step S102 from step S106. In this case, since the curtain travel correction necessity determination is sequentially performed during the period of power-on, the curtain travel correction can be executed in response to a situation where the curtain travel correction becomes necessary during power-on.

<4. Special Exposure by Adjusting Curtain Travel Curve>

Next, a technique for obtaining a special exposure effect by adjusting the curtain travel curve will be described. In other words, this is exposure difference imaging using a variable curtain travel curve.

By using the fact that the torque during curtain travel can be adjusted at the initial stage of traveling and at or after the middle stage of traveling, a captured image having an exposure difference between upper and lower portions of the image can be captured.

FIG. 53A illustrates a curtain travel curve in a normal uniform exposure state.

In this case, the curtain travel curves of the front curtain unit 334 and the rear curtain unit 335 have substantially the same shape, and the time during which the imaging element is exposed to light, that is, the exposure time is uniform between the upper and lower portions of the image.

FIG. 53A illustrates the exposure state (brightness and darkness) of the image by dot plot density.

Here, consider to perform imaging to make upper and lower portions darker than the center of the screen.

As illustrated in FIG. 53B, the torque at the initial stage of traveling of the rear curtain unit 335 is decreased and the torque at or after the middle stage of traveling of the rear curtain unit 335 is increased, relative to the front curtain unit 334. Then, the curtain travel curve of the rear curtain unit 335 becomes a curve in which rising at the initial stage of traveling is slow and acceleration at or after the middle stage of traveling is fast.

In this case, since upper and lower widths of the exposure time become narrower than that of the center of the screen, image data in which upper and lower portions of the screen are dark is captured.

Furthermore, consider to perform imaging to make upper and lower portions brighter than the center of the screen.

As illustrated in FIG. 53C, the torque at the initial stage of traveling of the front curtain unit 334 is decreased and the torque at or after the middle stage of traveling of the front curtain unit 334 is increased, relative to the rear curtain unit 335. Then, the curtain travel curve of the front curtain unit 334 becomes a curve in which rising at the initial stage of traveling is slow and acceleration at or after the middle stage of traveling is fast.

In this case, since upper and lower widths of the exposure time become wider than that of the center of the screen, image data in which upper and lower portions of the screen are bright is captured.

An example of curtain travel adjustment control for the special exposure by adjustment of the curtain travel curve by the main control unit 301 will be described with reference to FIG. 54. FIG. 54 illustrates a processing example mainly executed by the main control unit 301 according to the functions of the blade opening and closing device setting unit 302, the time length setting unit 303, and the current value setting unit 304.

When a power-on operation of the imaging apparatus 1 is performed by the user, the main control unit 301 performs power-on processing in step S201, and sets each unit to a state where imaging is possible.

In step S202, the main control unit 301 determines whether or not to perform the above-described exposure difference imaging. The exposure difference imaging is arbitrarily selected by the user, and normal imaging, a mode can be set to first exposure difference imaging, second exposure difference imaging by an operation of the operation unit 321, for example.

For description, the first exposure difference imaging is a mode to make upper and lower portions dark and make the center bright as in FIG. 53B, and the second exposure difference imaging is a mode to make the upper and lower portions bright and make the center dark as in FIG. 53C. In step S202, the main control unit 301 determines which mode has been selected and branches the processing.

When the normal imaging has been selected, the main control unit 301 sets the time length T and the current value Ar to normal mode setting (for example, default setting) for both the front curtain unit 334 and the rear curtain unit 335 in step S203.

Then, the main control unit 301 proceeds to step S204, and monitors the power-off operation by the user. Further, during the period in which the power-off operation is not performed, the main control unit 301 confirms whether or not the release determination is made, in other words, whether the user has pressed the shutter button 4 in step S205.

Further, in step S207, the main control unit 301 monitors whether or not a mode change operation by the user has been detected. Then, the main control unit 301 returns to step S204.

In the monitoring loop of steps S204, S205, and S207, in the case where the shutter operation is detected, the main control unit 301 proceeds to step S206 and performs exposure control. That is, the main control unit 301 instructs the blade opening and closing device control unit 329 to execute the curtain travel of the opening and closing blade 331 by the front curtain unit 334 and the rear curtain unit 335.

In the case where the time length T and the current value Ar are set to the normal mode setting, the curtain travel is performed with the curtain travel curve as in FIG. 53A in the front curtain unit 334 and the rear curtain unit 335. Therefore, normal imaging with a uniform exposure time over the entire screen is performed.

In the case where the mode change operation has been performed by the user, the main control unit 301 returns to step S202 from step S207, and branches the processing according to the selected mode.

In the mode state at the time of power-on or in the case where the mode of the first exposure difference imaging or the second exposure difference imaging has been selected by the mode operation of the user on or after the power-on, the main control unit 301 proceeds to step S210 from step S202. Then, the main control unit 301 proceeds to step S212 in the case of the first exposure difference imaging of making upper and lower portions of the image dark, and proceeds to step S211 in the case of the second exposure difference imaging of making the center of the image dark.

In the case of proceeding to step S212 by mode selection of the first exposure difference imaging, the main control unit 301 changes the setting of the time length T and the current value Ar to shorten the time length T of the rear curtain unit 335 and increase the current value Ar of the rear curtain unit 335, as compared with the normal mode.

Then, in the monitoring loop of steps S204, S205, and S207, in the case where the shutter operation is detected, the main control unit 301 proceeds to step S206 and performs exposure control. In this case, the curtain travel is performed with the curtain travel curve as in FIG. 53B in the front curtain unit 334 and the rear curtain unit 335, and imaging with an adjusted exposure time to make the center of the screen bright is performed.

In the case of proceeding to step S212 by mode selection of the second exposure difference imaging, the main control unit 301 changes the setting of the time length T and the current value Ar to shorten the time length T of the front curtain unit 334 and increase the current value Ar of the front curtain unit 334, as compared with the normal mode.

Then, in the monitoring loop of steps S204, S205, and S207, in the case where the shutter operation is detected, the main control unit 301 proceeds to step S206 and performs exposure control. In this case, the curtain travel is performed with the curtain travel curve as in FIG. 53C in the front curtain unit 334 and the rear curtain unit 335, and imaging with an adjusted exposure time to make the upper and lower portions of the screen bright is performed.

In a case where the power-off is determined due to a termination operation of the user, passage of time without operation, or the like, the main control unit 301 proceeds to step S208 from S204, and performs the power-off processing and terminates the series of control.

With the above processing, the special exposure imaging according to the mode selection of the user can be executed.

<5. Conclusion and Modification>

As described above, the imaging apparatus 1 of the present embodiment includes the motor mechanism (an electromagnetic actuator including the coil 31, the magnet 30, the yoke 32, and the like) that generates the traveling torque of the opening and closing blade of the mechanical shutter provided in the incident light path to the imaging element by the electric conduction to the coil, and the spring mechanism (power assist spring 55) that generates the traveling torque of the opening and closing blade 331 together with the motor mechanism. Moreover, the control unit (main control unit 301) capable of individually controlling the time length T from the start of the electric conduction to the coil 31 to the start of traveling of the opening and closing blade, and the current value Ar to be supplied to the coil 31 is provided.

In other words, the motor mechanism and the spring mechanism are provided to drive the opening and closing blade 331 that open and close as the mechanical shutter. Then, for example, when restriction by the lock mechanism is released, the opening and closing blade 331 is driven to travel by the combined torque of the motor torque and the spring torque. In this case, the time length T from the start of the electric conduction to the start of traveling (the time of the release of restriction by the lock mechanism) and the current value Ar to be supplied to the coil 31 are made individually and variably controllable.

The initial traveling torque of the opening and closing blade can be adjusted by the time length T from the start of the electric conduction to the coil to the start of traveling of the opening and closing blade (the time of the release of restriction by the lock mechanism). Since the motor torque increases with a predetermined time constant from the start of power supply, the motor torque increases at the time of unlock if the time length T is long. In this case, the initial traveling torque becomes large. Meanwhile, the motor torque does not sufficiently increase at the time of unlock if the time length T is short. In this case, the initial traveling torque is small.

Further, the traveling torque at or after the middle state of traveling of the opening and closing blade can be adjusted by varying the current value Ar (current setting value as a limit value) to be supplied to the coil. That is, since the set current value Ar is maintained at or after the middle stage, the traveling torque at or after the middle stage can be adjusted by the current value Ar.

Therefore, in the present embodiment, the traveling operation of the opening and closing blade can be easily adjusted by individually controlling the time length T and the current value Ar.

In other words, in the structure using the assist spring as the electromagnetic shutter as in the embodiment, the curtain travel curves at the initial stage and at or after the middle stage can be independently adjusted. Therefore, the shape of the curtain travel curve can be appropriately changed in units of traveling time.

In the embodiment, the main control unit 301 adjusts one or both of the time length T and the current value Ar to correct the traveling operation of the opening and closing blade 331 (see FIG. 51).

In other words, the traveling torque at the initial stage or the traveling torque at or after the middle stage of the opening and closing blade is adjusted to correct the traveling operation to an original traveling state.

Since the traveling torque at the initial stage or the traveling torque at or after the middle stage of the opening and closing blade can be adjusted according to the time length T and the current value Ar, the curtain travel curve indicating the traveling operation (the vertical position with respect to time progress) can be corrected according to the time length T and the current value Ar. Therefore, the traveling state of the opening and closing blade can be corrected in a case where the original traveling cannot be realized due to deterioration over time, parts error, or other factors.

For example, even in a case where the spring torque for curtain travel varies due to manufacturing variations of the power assist spring 55, the manufacturing variations of the power assist spring 55 can be corrected by simply adjusting unlock time to change the time length T.

For example, appropriately correcting occurrence of curtain unevenness is possible.

Further, since such correction is possible, adjustment work in the manufacturing process of the imaging apparatus 1 is made efficient, and the manufacturing cost is also reduced.

Further, at the time of use on the user side, even if change in the spring torque by the power assist spring 55 or the motor torque by the motor mechanism occurs due to aging, repetitive operation, or the like, appropriate correction can be performed. For example, in a case where a rotational resistance of the opening and closing blade is increased only at the initial stage or only at or after the middle stage due to deterioration over time or the like, the travel curve of the opening and closing blade can be appropriately adjusted by increasing the torque for only a portion where the resistance is increased. Therefore, imaging with appropriate exposure can be maintained.

In the embodiment, an example in which the durability counter 341 for measuring the number of times of traveling of the opening and closing blade 331 is included, and the main control unit 301 corrects the curtain travel curve on the basis of the count value of the durability counter 341 has been described (see FIGS. 51 and 52A).

The deterioration state over time of the mechanism can be estimated according to the number of times of traveling of the opening and closing blade 331. Therefore, correction is required in the case where a predetermined number of times of curtain travel has been performed. As a result, the correction operation corresponding to the deterioration over time can be realized.

Note that the correction according to the number of times of traveling can be performed by statistically checking torque variation over time. For example, a plurality of thresholds of the number of times of curtain travel is provided such as thresholds thNC1, thNC2, thNC3, and the like, and the time value T may be changed in a stepwise manner according to the progress of the number of times of curtain travel, or the setting of the current limit value Ar may be changed in a stepwise manner. Thereby, the correction of the curtain travel curve more appropriately corresponding to the state over time can be realized.

Alternatively, a control example is further conceivable in which the time value T is changed when the number of times of curtain travel becomes the threshold thNC1 or higher, and then the current limit value Ar1 is changed when the number of times of curtain travel becomes the threshold thNC2 or higher.

In the embodiment, an example in which the curtain speed sensor 336 is included as the speed sensor of the opening and closing blade 331, and the main control unit 301 corrects the curtain travel curve on the basis of the detection information of the curtain speed sensor 336 has been described (see FIGS. 51 and 52C).

A change in the traveling operation (decrease in speed) due to deterioration of the motor mechanism or the spring mechanism can be detected by the speed sensor. Therefore, the traveling torque at the initial stage or the traveling torque at or after the middle stage can be adjusted by detecting the case where correction is necessary according to the detection value of the speed sensor.

Of course, it is conceivable to adjust the correction amount (the change amount of the time value T and the change amount of the current limit value Ar) according to the speed.

In the embodiment, an example in which the drive source temperature sensor 342 for detecting the temperature of the motor mechanism or the spring mechanism is included, and the main control unit 301 corrects the curtain travel curve on the basis of the detection information of the drive source temperature sensor 342 has been described (see FIGS. 51 and 52B).

A case where the performance of the motor mechanism or the spring mechanism has been changed due to temperature can be detected by temperature sensor. Therefore, the traveling torque at the initial stage or the traveling torque at or after the middle stage can be adjusted by detecting the case where correction is necessary according to the detection value of the temperature sensor (the case where the temperature becomes a predetermined high temperature or higher, for example).

That is, at the time of use on the user side, even if change in torque occurs in the spring mechanism (power assist spring 55) or the motor mechanism due to the surrounding environment, a temperature rise of the actuator, or the like, appropriate correction can be performed.

Of course, it is conceivable to adjust the correction amount (the change amount of the time value T and the change amount of the current limit value Ar) according to the temperature.

Note that a humidity sensor for detecting the humidity around the motor mechanism or the spring mechanism or around the opening and closing blade is provided, and the control unit 300 may perform correction on the basis of detection information of the humidity sensor. The performance change may occur in the motor mechanism or the spring mechanism or the traveling operation of the opening and closing blade may be affected by the humidity. Therefore, it is useful to adjust the traveling torque at the initial stage and at or after the middle stage according to the humidity.

Furthermore, the correction necessity determination based on the number of times of curtain travel, the correction necessity determination based on the temperature sensor, and the correction necessity determination based on the curtain speed sensor may be performed in a composite manner.

Furthermore, it is also conceivable to perform the correction necessity determination or the correction amount setting on the basis of information other than the curtain speed sensor 336, the drive source temperature sensor 342, and the durability counter 341.

In the embodiment, the motor mechanism and the spring mechanism corresponding to the opening and closing blade 331 as the front curtain unit 334 are included, and the motor mechanism and the spring mechanism corresponding to the opening and closing blade 331 as the rear curtain unit 335 are included. Then, the main control unit 301 corrects the curtain travel curve for one or both of the front curtain unit 334 and the rear curtain unit 335.

In other words, correction can be performed in the mechanism that performs the shutter operation with a front curtain and a rear curtain.

For example, by correcting the curtain travel curve of the rear curtain mechanism to match the curtain travel curve of the front curtain mechanism, the exposure time can be made constant in lines of a captured image. That is, the curtain travel curve of the rear curtain mechanism can be corrected with reference to the curtain travel curve of the front curtain mechanism.

Conversely, by correcting the curtain travel curve of the front curtain mechanism to match the curtain travel curve of the rear curtain mechanism, the exposure time can be made constant in lines of a captured image. That is, the curtain travel curve of the front curtain mechanism can be corrected with reference to the curtain travel curve of the rear curtain mechanism.

Moreover, the curtain travel curve of the front curtain mechanism and the curtain travel curve of the rear curtain mechanism can be corrected to match a reference curtain travel curve. The exposure time in lines of a captured image can be made constant. That is, both the curtain travel curve of the front curtain mechanism and the curtain travel curve of the rear curtain mechanism may be corrected.

In the embodiment, an example in which the main control unit 301 adjusts one or both of the time length T and the current value Ar according to the selected imaging mode (normal imaging, first exposure difference imaging, or second exposure difference imaging) (see FIGS. 53 and 54).

Since the traveling torque at the initial stage or the traveling torque at or after the middle stage of the opening and closing blade can be adjusted according to the time length T and the current value Ar, the curtain travel curve indicating the traveling operation (the vertical position with respect to time progress) can be variably set according to the time length T and the current value Ar. By adjusting the curtain travel curve, imaging of intentionally obtaining a special image effect can be realized. For example, since an exposure value with respect to the center of the screen can be adjusted, the amount of light around the lens can be corrected, or expression can be changed depending on a photograph to be captured.

In the embodiment, an example in which the main control unit 301 adjusts one or both of the time length T and the current value Ar such that the exposure time of a center of an image becomes longer than the exposure time of an end portion of the image in the up-down direction according to selection of the imaging mode (first exposure difference imaging) for making a center of an image brighter than an end portion of an image in the up-down direction has been described (see step S212 in FIG. 54).

In other words, the curtain travel curve of the opening and closing blade is changed to take the exposure time long in the center of the image.

As a result, imaging of making a central portion in the up-down direction of a captured image bright can be easily realized. For example, to obtain an image with a bright central portion, it is necessary to attach a filter that reduces the amount of light of upper and lower end portions. However, in the present embodiment, imaging of emphasizing the center of the image can be performed without using such a special device.

In the embodiment, an example in which the main control unit 301 adjusts one or both of the time length T and the current value Ar such that the exposure time of a center of an image becomes shorter than the exposure time of an end portion of the image in the up-down direction according to selection of the imaging mode (second exposure difference imaging) for making upper and lower end portions of an image brighter than a center of the image in the up-down direction has been described (see step S211 in FIG. 54).

In other words, a curtain travel curve of the opening and closing blade is varied to take the exposure time short in the center of the image.

As a result, imaging of making upper and lower end portions a captured image bright can be easily realized. For example, it is not necessary to attach a filter that reduces the amount of light at the center of the image.

In the embodiment, an example in which the motor mechanism and the spring mechanism corresponding to the opening and closing blade 331 as the front curtain unit 334 are included and the motor mechanism and the spring mechanism corresponding to the opening and closing blade 331 as the rear curtain unit 335 are included, and the main control unit 301 adjusts the curtain travel curve of one or both of the front curtain unit 334 and the rear curtain unit 335 has been described (FIG. 54).

In other words, in the mechanism that performs shutter operation with a front curtain and a rear curtain, the curtain travel curves of the front curtain and the rear curtain are varied to obtain a special image effect.

For example, by causing the front curtain mechanism to travel with a reference curtain travel curve, and adjusting the rear curtain mechanism, the exposure time in upper and lower end portions or a central portion can be changed.

Conversely, by causing the rear curtain mechanism to travel with a reference curtain travel curve, and adjusting the front curtain mechanism, the exposure time in upper and lower end portions or a central portion can be changed.

Of course, the exposure time at upper and lower positions of an image can be variously set by adjusting both the front curtain mechanism and the rear curtain mechanism.

In the embodiment, an example in which the lock mechanism (lock lever 333) for restricting the opening and closing blade 331 not to start traveling by energization of the spring mechanism (power assist spring 55) or the start of the electric conduction to the coil 31 is included has been described.

The opening and closing blade 331 can be maintained not to start traveling by the spring torque or the motor torque by being restricted by the lock mechanism. In other words, a mechanism in which the unlock timing of the lock mechanism becomes the curtain travel start timing is formed, and the time length T can be accurately controlled by the mechanism.

In particular, the main control unit 301 varies the time length T according to restriction release timing by the lock mechanism after the start of the electric conduction to the coil 31.

After the start of the electric conduction to the coil 31, the time when the restriction by the lock mechanism is released is travel start timing of the opening and closing blade.

Therefore, if the timing to release the restriction is adjusted by the lock mechanism, the time length from the start of the electric conduction to the coil to the start of traveling of the opening and closing blade can be adjusted. As a result, the initial torque can be easily controlled only by setting timing of two signals of an energization start control signal (motor signal) and an unlock signal.

Further, the motor mechanism of the embodiment includes the coil 31 to which the drive current is supplied and the magnet 30 rotated with the electric conduction to the coil 31, and the spring mechanism has a configuration to energize the magnet 30 in the rotation direction. Further, the drive body (drive lever 40) causing the opening and closing blade 331 to travel according to the rotation of the magnet 30 and including the portion to be locked (engagement piece 43), and the lock mechanism (the first lock mechanism 66 or the second lock mechanism 67) has a configuration to maintain the opening and closing blade 331 not to start traveling by the engagement with the portion to be locked.

In other words, the motor mechanism (so-called electromagnetic actuator) for driving the opening and closing blade 331 includes the magnet 30 rotated with the electric conduction to the coil 31, and the drive lever 40 causes the opening and closing blade 331 to travel with the rotation of the magnet 30.

In this structure, the drive lever 40 is provided with the engagement piece 43, and the lock lever 70 in the lock mechanism (66 or 67) locks the engagement piece 43, whereby restriction not to start traveling can be performed by the electric conduction to the coil.

Further, in the embodiment, the spring mechanism has a configuration to energize the magnet 30 in the rotation direction.

The spring mechanism energizes the magnet 30 constituting an electromagnetic actuator to provide the drive body (drive lever 40) with a spring torque for causing the opening and closing blade 331 to travel.

As a result, a mechanism for providing the spring torque and the motor torque can be realized with the simple configuration.

Note that the present technology is not limited to the examples of the embodiment, and various modifications can be considered in addition to the examples mentioned as the configurations and processing examples.

Although the embodiment has the configuration including the front curtain unit 334 and the rear curtain unit 335, a so-called single-screen configuration may be adopted. For example, one curtain unit may be included and the exposure period may be defined by the electronic shutter timing of the imaging element unit 325.

Specifically, one curtain mechanism is caused to work as the front curtain unit 334, and the function of the rear curtain unit 335 may be realized by the electronic shutter of the imaging element unit. Conversely, one curtain mechanism is caused to work as the rear curtain unit 335, and the function of the front curtain unit 334 may be realized by the electronic shutter of the imaging element unit.

Note that the effects described in the present specification are merely examples and are not limited, and other effects may be exhibited.

Note that the present technology can also have the following configurations.

(1)

An imaging apparatus including:

a motor mechanism configured to generate a traveling torque of an opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil;

a spring mechanism configured to generate the traveling torque of the opening and closing blade together with the motor mechanism; and

a control unit configured to be able to individually control a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade, and a current value to be supplied to the coil.

(2)

The imaging apparatus according to (1), in which

the control unit adjusts one or both of the time length and the current value to correct a traveling operation of the opening and closing blade.

(3)

The imaging apparatus according to (2), further including:

a counter configured to count the number of times of traveling of the opening and closing blade, in which

the control unit performs the correction on the basis of a count value of the counter.

(4)

The imaging apparatus according to (2) or (3), further including:

a speed sensor of the opening and closing blade, in which

the control unit performs the correction on the basis of detection information of the speed sensor.

(5)

The imaging apparatus according to any one of (2) to (4), further including:

a temperature sensor configured to detect a temperature of the motor mechanism or the spring mechanism, in which

the control unit performs the correction on the basis of detection information of the temperature sensor.

(6)

The imaging apparatus according to any one of (2) to (5), including:

the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism; and

the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism, in which

the control unit performs the correction of one or both of the front curtain mechanism and the rear curtain mechanism.

(7)

The imaging apparatus according to (1), in which

the control unit adjusts one or both of the time length and the current value according to a selected imaging mode.

(8)

The imaging apparatus according to (7), in which

the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes longer than an exposure time of an end portion of the image in an up-down direction according to selection of an imaging mode for making a center of an image brighter than an end portion of the image in the up-down direction.

(9)

The imaging apparatus according to (7), in which the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes shorter than an exposure time of upper and lower end portions of the image in an up and down direction according to selection of an imaging mode for making upper and lower end portions of an image brighter than a center of the image in the up and down direction.

(10)

The imaging apparatus according to any one of (7) to (9), including:

the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism; and

the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism, in which

the control unit performs the adjustment of one or both of the front curtain mechanism and the rear curtain mechanism.

(11)

The imaging apparatus according to any one of (1) to (10), further including:

a lock mechanism configured to restrict the opening and closing blade not to start traveling even by energization of the spring mechanism and the start of the electric conduction to the coil.

(12)

The imaging apparatus according to (11), in which

the control unit varies the time length according to restriction release timing by the lock mechanism after the start of the electric conduction to the coil.

(13)

The imaging apparatus according to (11), in which

the motor mechanism includes a coil to which a drive current is supplied, and a magnet rotated with the electric conduction to the coil,

the spring mechanism is configured to energize the magnet in a rotation direction,

a drive body configured to cause the opening and closing blade to travel according to rotation of the magnet and including a portion to be locked, and

the lock mechanism is configured to maintain the opening and closing blade not to start traveling by locking the portion to be locked.

(14)

The imaging apparatus according to (13), in which

the spring mechanism is configured to energize the magnet in the rotation direction.

(15)

A shutter driving method of an imaging apparatus including

a motor mechanism configured to generate a traveling torque of an opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil, and

a spring mechanism configured to generate the traveling torque of the opening and closing blade together with the motor mechanism, the shutter driving method including:

a procedure of setting a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade; and

a procedure of setting a current value to be supplied to the coil.

REFERENCE SIGNS LIST

-   1 Imaging apparatus -   11 Blade opening and closing device -   30 Magnet -   31 Coil -   32 Yoke -   40 Drive lever -   55 Power assist spring -   66 First lock mechanism -   67 Second lock mechanism -   70 Lock lever -   301 Main control unit -   302 Blade opening and closing device setting unit -   303 Time length setting unit -   304 Current value setting unit -   306 Signal processing unit -   307 Recording processing unit -   321 Operation unit -   324 Recording unit -   325 Imaging element unit -   327 Display device -   328 UI control unit -   329 Blade opening and closing device control unit -   330 Electromagnetic drive source -   331 Opening and closing blade -   332 Lock drive source -   333 Lock lever -   334 Front curtain unit -   335 Rear curtain unit -   341 Durability counter -   342 Drive source temperature sensor -   336 Curtain speed sensor -   337 Detection value storage unit 

1. An imaging apparatus comprising: a motor mechanism configured to generate a traveling torque of an opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil; a spring mechanism configured to generate the traveling torque of the opening and closing blade together with the motor mechanism; and a control unit configured to be able to individually control a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade, and a current value to be supplied to the coil.
 2. The imaging apparatus according to claim 1, wherein the control unit adjusts one or both of the time length and the current value to correct a traveling operation of the opening and closing blade.
 3. The imaging apparatus according to claim 2, further comprising: a counter configured to count the number of times of traveling of the opening and closing blade, wherein the control unit performs the correction on a basis of a count value of the counter.
 4. The imaging apparatus according to claim 2, further comprising: a speed sensor of the opening and closing blade, wherein the control unit performs the correction on a basis of detection information of the speed sensor.
 5. The imaging apparatus according to claim 2, further comprising: a temperature sensor configured to detect a temperature of the motor mechanism or the spring mechanism, wherein the control unit performs the correction on a basis of detection information of the temperature sensor.
 6. The imaging apparatus according to claim 2, comprising: the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism; and the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism, wherein the control unit performs the correction of one or both of the front curtain mechanism and the rear curtain mechanism.
 7. The imaging apparatus according to claim 1, wherein the control unit adjusts one or both of the time length and the current value according to a selected imaging mode.
 8. The imaging apparatus according to claim 7, wherein the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes longer than an exposure time of an end portion of the image in an up-down direction according to selection of an imaging mode for making a center of an image brighter than an end portion of the image in the up-down direction.
 9. The imaging apparatus according to claim 7, wherein the control unit adjusts one or both of the time length and the current value such that an exposure time of a center of an image becomes shorter than an exposure time of upper and lower end portions of the image in an up and down direction according to selection of an imaging mode for making upper and lower end portions of an image brighter than a center of the image in the up and down direction.
 10. The imaging apparatus according to claim 7, comprising: the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a front curtain mechanism; and the motor mechanism and the spring mechanism corresponding to the opening and closing blade as a rear curtain mechanism, wherein the control unit performs the adjustment of one or both of the front curtain mechanism and the rear curtain mechanism.
 11. The imaging apparatus according to claim 1, further comprising: a lock mechanism configured to restrict the opening and closing blade not to start traveling even by energization of the spring mechanism and the start of the electric conduction to the coil.
 12. The imaging apparatus according to claim 11, wherein the control unit varies the time length according to restriction release timing by the lock mechanism after the start of the electric conduction to the coil.
 13. The imaging apparatus according to claim 11, wherein the motor mechanism includes a coil to which a drive current is supplied, and a magnet rotated with the electric conduction to the coil, the spring mechanism is configured to energize the magnet in a rotation direction, a drive body configured to cause the opening and closing blade to travel according to rotation of the magnet and including a portion to be locked, and the lock mechanism is configured to maintain the opening and closing blade not to start traveling by locking the portion to be locked.
 14. The imaging apparatus according to claim 13, wherein the spring mechanism is configured to energize the magnet in the rotation direction.
 15. A shutter driving method of an imaging apparatus including a motor mechanism configured to generate a traveling torque of an opening and closing blade of a mechanical shutter provided in an incident light path to an imaging element by electric conduction to a coil, and a spring mechanism configured to generate the traveling torque of the opening and closing blade together with the motor mechanism, the shutter driving method comprising: a procedure of setting a time length from start of the electric conduction to the coil to start of traveling of the opening and closing blade; and a procedure of setting a current value to be supplied to the coil. 